FM 20-32 (Mine Countermine Operations)

This reprint includes Changes 1, 2, and 3.

FM 20-32

^^p_^ Mine/Countermine

^^^^^ Operations

Headquarters,
Department of the Army

DISTRIBUTION RESTRICTION: Approved for public release; distribution is unlimited.

Change 3

FM 20-32
C3

Headquarters

Department of the Army

Washington, DC, 1 October 2002

Mine/Countermine Operations

1. Change FM 20-32, 29 May 1998, as follows:

Remove Old Pages

v through x

xiii through xvi

11-7 through 11-25

A- 11 and A- 12

F-3 through F-20

G-7 and G-8

Index- 1 through Index-6

Insert New Pages

v through x

xiii through xvi

11-7 through 11-26

A- 11 and A- 12

F-3 through F-23

G-7 and G-8

Index- 1 through Index-6

2. A bar ( | ) marks new or changed material.

3. File this transmittal sheet in front of the publication.

DISTRIBUTION RESTRICTION: Approved for public release; distribution is unlimited.
By Order of the Secretary of the Army:

ERIC K. SHINSEKI

General, United States Army

Chief of Staff

Official:

JOEL B. HUDSON

Administrative Assistant to the
Secretary of the Army
0226802

DISTRIBUTION:

Active Army, Army National Guard, and US Army Reserve: To be distributed in accordance with the
initial distribution number 111053, requirements for FM 20-32.

Change 2

FM 20-32
C2

Headquarters

Department of the Army

Washington, DC, 22 August 2001

Mine/Countermine Operations

1. Change FM 20-32, 30 September 1992, as follows:

Remove Old Pages Insert New Pages

i through xviii
1-5 through 1-8
2-9 and 2-10
2-21 and 2-22
2-45 and 2-46
3-1 through 3-8
3-13 and 3-14
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4-11 and 4-12
4-15

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9-7

10-1 through 10-4
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Remove Old Pages

Insert New Pages

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D-5 and D-6

D-15andD-16

E-l and E-2

F-3 and F-4

F-9andF-10

F- 17 and F- 18

Glossary-7 through Glossary-10

References- 1 and References-3

Index- 1 through Index- 6

DA Form 1355- 1-R

12-15 and 12-16

13-1 through 13-6

13-15 and 13-16

13-21 and 13-22

13-29 through 13-33

A-llandA-12

A-29 and A-30

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F-9andF-10

F-17andF-18

Glossary-7 through Glossary-10

References- 1 and References-3

Index- 1 through Index- 6

DA Form 1355- 1-R

2. A bar ( | ) marks new or changed material.

3. File this transmittal sheet in front of the publication.

4. This change includes Change 1, 30 June 1999.

DISTRIBUTION RESTRICTION: Approved for public release; distribution is unlimited.
By Order of the Secretary of the Army:

ERIC K. SHINSEKI

General, United States Army
Chief of Staff
Official:

JM&JtJJLJ

JOEL B. HUDSON
Administrative Assistant to the
Secretary of the Army
0121803
DISTRIBUTION:

Active Army, Army National Guard, and US Army Reserve: To be distributed in accordance
with the initial distribution number 111053, requirements for FM 20-32.

FM 20-32
CI

Change 1 H eadquarters

Department of the Army
Washington, DC, 30J unel999

MINE/COUNTERMINE OPERATIONS

1. Change FM 20-32, 29 May 1998, as follows:

Page 13-32. After the first paragraph add the foil owing:

NOTE : The United Nations Convention of Certain Conventional Weapons (CCW)
mandates that all fragment munitions produce fragments that are visible by x-ray
(such as metal or rock).

PageA-33. Ml AND M2 ACTIVATORS, third paragraph, line 1, change "533 millimeters
long" to "54 millimeters long (with cap)."

PageA-33. Ml AND M2 ACTIVATORS, third paragraph, line 5, change "190" to "25."

PageA-33. Ml AND M2 ACTIVATORS, fourth paragraph, line 2, delete entire line and add
"its overall length, with cap, is 53 millimeters."

2. Post these changes according to DA Pamphlet 310-13.

3. Filethis transmittal sheet in the front of the publication .

DISTRIBUTION RESTRICTION. Approved for public release; distribution is unlimited.

FM 20-32
CI, 30 June 1999

By Order of the Secretary of the Army:

ERIC K. SHINSEKI

General, United States Army

Chief of Staff

Official:

JOEL B. HUDSON
Administrative Assistant to the
Secretary of the Army
9916103

DISTRIBUTION:

Active Army, Army National Guard, and US Army Reserve: To be distributed in accordance with the initial
distribution number 1 1 1053, requirements for FM 20-32.

C2

*FM 20-32

Field Manual Headquarters

No. 20-32 Department of the Army

Washington, DC, 29 May 1998

MINE/COUNTERMINE OPERATIONS

Table of Contents

Page

LIST OF ILLUSTRATIONS x

Figures x

Tables xv

PREFACE xvii

CHAPTER 1. INTRODUCTION 1-1

MECHANICS OF MINES 1-1

Characteristics and Functioning 1-1

Components and I nitiating Actions 1-2

ANTITANK MINES 1-4

Types of Kills 1-4

Types of Sensing 1-5

Types of Warheads 1-5

ANTIPERSONNEL MINES 1-5

Types of Kills 1-5

Types of Sensing 1-6

Types of Effects 1-6

ANTI HANDLING DEVICES 1-6

Part One. Mine Operations

CHAPTER 2. MINE-WARFARE PRINCIPLES 2-1

MINE-WARFARE CONCEPTS 2-1

TYPES OF MINEFIELDS 2-1

Protective Minefields 2-2

Tactical Minefields 2-3

Nuisance Minefields 2-4

Phony Minefields 2-4

PROTECTIVE VERSUS TACTICAL MINEFIELDS 2-5

TACTICAL MINEFIELDS 2-5

Minefield Variables 2-7

Design 2-10

DISTRIBUTION RESTRICTION: Approved for public release; distribution is unlimited.

'This manual supersedes FM 20-32, 30 September 1992.

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Page

TACTICAL-OBSTACLE INTEGRATION PRINCIPLES 2-14

Obstacle Emplacement Authority 2-14

Obstacle Control 2-14

Obstacle Control Measures 2-15

Fratricide Prevention 2-19

Maneuver-Plan Support 2-19

SITING AND EMPLACING TACTICAL MINEFIELDS 2-32

Coordinating with the M aneuver Commander 2-32

Siting the M inefield 2-37

Emplacing Minefields 2-39

Determining Resource Requirements 2-39

MINEFIELD SUPPLY OPERATIONS 2-39

Resupply Nodes 2-41

Resupply Rules 2-43

Supply Location 2-44

Resupply Methods 2-44

MINEFIELD MARKING 2-49

Criteria 2-49

Perimeter 2-50

Techniques 2-50

MINEFIELD TURNOVER 2-52

MINEFIELD INSPECTION AND MAINTENANCE 2-55

CHAPTER 3. SCATTERABLE MINES AND MINE DELIVERY SYSTEMS 3-1

GENERAL CHARACTERISTICS 3-1

Antipersonnel Mines 3-1

Antitank Mines 3-3

CAPABILITIES 3-5

Faster Response 3-5

Remote Placement 3-5

Increased Tactical Flexibility 3-5

Efficiency 3-5

Increased Lethality 3-5

LIMITATIONS 3-5

Extensive Coordination 3-5

Proliferation of Targets 3-6

Visibility 3-6

Accuracy 3-6

Orientation 3-6

LIFE CYCLE 3-6

LETHALITY AND DENSITY 3-7

Lethality and Tactical-Obstacle Effect 3-7

Density 3-8

COMMAND AND CONTROL 3-9

AUTHORITY 3-9

COORDINATION 3-10

EMPLOYMENT AND EMPLACEMENT 3-10

Area-Denial Artillery Munitions and Remote Antiarmor Mines 3-11

Gator 3-14

Volcano 3-17

Modular Pack Mine System 3-27

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Page

MARKING 3-26

Safety Zones 3-27

Fragment Hazard Zones 3-27

Fencing 3-28

CHAPTER 4. SPECIAL -PURPOSE MUNITIONS 4-1

M18A1 CLAYMORE 4-2

SELECTABLE LIGHTWEIGHT ATTACK MUNITION 4-3

Operating Modes 4-3

Antitamper Feature 4-6

M 93 HORNET 4-6

Employment Considerations 4-7

Employment Roles 4-7

Tactical Emplacement 4-8

Recording and Marking 4-15

CHAPTER 5. CONVENTIONAL MINES 5-1

ANTITANK MINES 5-1

M15 5-1

M19 5-2

M21 5-2

ANTIPERSONNEL MINES 5-3

M14 5-3

M16 5-4

EM PLACING MINES 5-4

Mines With Prongs 5-4

Mines With Pressure Plates 5-4

Mines With Tilt Rods 5-6

Bearing Boards 5-6

Concealment 5-6

Maneuver Assistance 5-8

CHAPTER 6. ROW MINING 6-1

USE 6-1

RULES 6-1

LOGISTICS 6-3

Calculations 6-3

Task Organization 6-14

Site Layout 6-16

Mine-Laying Vehicles 6-18

Laying a Row Minefield 6-18

Immediate-Action Drill 6-24

Squad Drill 6-24

Marking, Recording, and Reporting Row Minefields 6-25

STANDARDIZED TACTICAL ROW Ml NEFI ELDS 6-25

Disrupt and Fix 6-28

Turn 6-29

Block 6-31

HASTY PROTECTIVE ROW Ml NEFI ELDS 6-33

Rules 6-34

Site Layout 6-34

mi

Page

CHAPTER 7. STANDARD-PATTERN MINEFIELDS 7-1

COMPONENTS 7-1

Mine Strips 7-1

Mine Clusters 7-1

Rules for Positioning Clusters Within a Strip 7-2

Standard-Pattern Minefield Rules 7-4

LOGISTICAL CALCULATIONS 7-9

Cluster Calculation 7-9

Platoon Organization 7-10

Mine-Emplacement Procedures 7-11

Mine Emplacement 7-13

NUISANCE MINEFIELDS 7-17

Siting 7-17

Location 7-17

Laying 7-18

Inspection and Maintenance 7-18

Handover 7-19

CHAPTER 8. REPORTING AND RECORDING 8-1

MINEFIELD/MUNITION FIELD REPORTS 8-1

Report of Intention 8-1

Report of Initiation 8-1

Report of Completion 8-2

Report of Transfer 8-2

Report of Change 8-3

Progress Reports 8-3

MINEFIELD/MUNITION FIELD RECORDS 8-3

Minefield Record 8-4

Hasty Protective Row Minefield Record 8-17

Nuisance Minefield 8-20

SCATTERABLE MINEFIELD/MUNITION FIELD REPORTING AND RECORDING 8-20

MINEFIELD/MUNITION FIELD OVERLAY SYMBOLS 8-25

Part Two. Counteroperations

CHAPTER 9. COUNTERMINE OPERATIONS 9-1

DEFINITIONS 9-1

Obstacle 9-1

Reduction 9-1

Breaching 9-1

Area Clearance 9-1

Route Clearance 9-1

Mine Neutralization 9-1

Proofing 9-2

Demining 9-2

BREACHING OPE RATIONS 9-2

Intelligence 9-2

Fundamentals 9-4

Organization 9-4

Mass 9-5

Synchronization 9-5

IV

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Page

CLEARING OPE RATIONS 9-6

Upgrade of Breach Lanes 9-6

Area Clearance 9-7

Demining 9-7

CHAPTER 10. MINEFIELD REDUCTION 10-1

DETECTING 10-1

Visual 10-1

Physical 10-2

Electronic 10-3

Mechanical 10-6

REPORTING 10-7

REDUCING 10-7

Explosive 10-7

Mechanical 10-14

Electronic 10-22

Manual 10-22

PROOFING 10-24

MARKING 10-24

Lane-Marking Terms 10-25

Levels of Lane Marking and Patterns 10-27

Commander's Guidance for Lane Marking 10-33

Lane-Marking Devices 10-34

Marking Requirements of the North Atlantic Treaty Organization 10-36

CHAPTER 11. ROUTE AND AREA CLEARANCE 11-1

ROUTE CLEARANCE 11-1

Planning 11-1

Planning Considerations 11-3

Task Organization 11-7

Methods and Types 11-11

AREA CLEARANCE 11-15

Planning 11-16

Planning Considerations 11-17

Task Organization 11-18

Methods and Types 11-18

IMPROVISED MINE THREAT 11-19

MINE LOCATIONS 11-20

DISPOSITION OF MINES 11-20

Mine-Removal Techniques 11-21

Hand Neutralization 11-21

SAFETY 11-22

REPORTS 11-22

Situation Report 11-23

Progress Report 11-23

Mine Incident Report 11-26

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Page
Part Three. Special Mining Operations

CHAPTER 12. MINING OPERATIONS IN SPECIAL ENVIRONMENTS 12-1

STREAM BED AND RIVER MINING 12-1

Employment 12-1

Emplacement 12-2

Recovery 12-3

Recording 12-3

Safety 12-3

URBAN-TERRAIN MINING 12-6

Antipersonnel Mines 12-7

Conventional Antitank Mines 12-12

Scatterable Mines 12-13

Deception Measures 12-15

SPECIAL ENVIRONMENTS 12-16

Cold Regions 12-16

J ungles 12-17

Deserts 12-17

CHAPTER 13. BOOBYTRAPS AND EXPEDIENT DEVICES 13-1

Section I . Setting Booby Traps 13-1

TACTICS 13-2

SITING 13-4

TYPES OF TRAPS 13-4

COM PONE NTS AND PRINCIPLES 13-5

ACTUATION METHODS 13-5

METHODS OF CONNECTION 13-5

Remote 13-5

Direct 13-8

PLANNING, SETTING, AND RECORDING 13-8

Timeliness 13-8

Orders and Briefing 13-8

Rehearsal 13-9

Organization and Procedure 13-9

Reporting and Recording 13-10

SITES 13-14

SAFETY 13-14

Section 1 1 . Clearing Booby Traps 13-14

INDICATIONS 13-15

DETECTION 13-15

CLEARING METHODS 13-15

COMBAT CLEARANCE 13-16

CLEARANCE IN SECURE AREAS 13-17

Policy and Planning 13-17

Control Point 13-18

Control and Size of Parties 13-18

Marking 13-18

Clearing of Open Areas 13-18

Clearing of Buildings 13-19

Exterior Reconnaissance and Entry 13-19

Search Techniques 13-19

VI

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Page

Clearing I retaliations and Facilities 13-21

Clearing Obstacles 13-21

Clearing Secure Areas 13-21

CLEARANCE METHODS 13-22

IMPROVISED TRAPS 13-23

NON EXPLOSIVE TRAPS 13-23

Punji 13-23

Closing Trap 13-23

Spike Board 13-28

Venus Flytrap 13-28

Section III. Expedient Devices 13-29

AUTHORIZATION 13-29

EMPLOYMENT AND CONSTRUCTION TECHNIQUES 13-29

High-Explosive, Artillery-Shell Antitank Device 13-30

Platter Charge 13-31

Improvised Claymore 13-31

Grapeshot Antipersonnel Device 13-32

Barbwi re Antipersonnel Device 13-32

APPENDIX A. INSTALLATION AND REMOVAL OF US MINES

AND FIRING DEVICES A-l

Section I. Antipersonnel Mines A-2

M14 A-2

Characteristics A-2

Installation A-3

Removal A-5

M16 A-6

Characteristics A-6

Installation A-7

Removal A-10

Section 1 1 . Antitank Mines A-ll

M15 A-ll

Characteristics A-12

Installation U sing the M 624 Fuse A-13

Removal Using the M624 Fuse A-17

Installation U sing the M 603 Fuse A-17

Removal Using the M603 Fuse A-20

M19 A-21

Characteristics A-22

Installation A-22

Removal A-24

M21 A-24

Characteristics A-25

Installation A-26

Removal A-29

Section III. Firing Devices and Activators A-29

M5 PRESSURE-RELEASE FIRING DEVICE (MOUSETRAP) A-30

Characteristics A-30

Installation A-31

Removal A-31

VII

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Page

M 142 MULTIPURPOSE FIRING DEVICE A-32

Characteristics A-33

Arming and Disarming A-33

Ml AND M 2 ACTIVATORS A-33

APPENDIX B. CONTROLS AND COMPONENTS OF

SPECIAL-PURPOSE MUNITIONS B-l

SELECTABLE LIGHTWEIGHT ATTACK MUNITION B-l

M 93 HORNET B-l

APPENDIX C. THREAT MINE/COUNTERMINE OPERATIONS C-l

MINE OPERATIONS C-l

CHEMICAL MINES C-6

COUNTERMINE OPERATIONS C-7

Organization C-7

Equipment C-ll

APPENDIX D. AIR VOLCANO D-l

COMPONENTS D-l

M87-Series Mine Canister D-l

M 139 Dispenser D-2

LIMITATIONS D-2

EMPLOYMENT D-2

Deep Operations D-3

Close Operations D-4

Rear Operations D-5

Minefield Effects D-6

Planning D-8

EMPLACEMENT D-18

Outside Friendly Territory D-20

Within Friendly Territory D-20

REPORTING D-22

Scatterable Minefield Warning D-22

Scatterable Minefield Report and Record D-22

APPE NDIX E . SAFETY AND TRAI Nl NG E-l

STORAGE E-l

LIVE-MINE TRAINING E-3

LIVE-MINE DEMONSTRATIONS E-5

M 16 Antipersonnel Mine E-5

M18A1 Antipersonnel Munition E-6

M15, M19, and M21 Antitank Mines E-7

RISK ASSESSMENT FOR LIVE-MINE DEMONSTRATIONS E-8

RISK ASSESSMENT FOR LIVE-MINE TRAINING E-10

APPENDIX F. MINE AWARENESS F-l

SOLDIER F-l

Visual Indicators F-l

Probing F-2

AN/PSS-12 Metallic Mine Detector F-3

Evacuation Drills F-13

VIM

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LEADER F-17

Risk Management F-17

Recording and Mine-Data Tracking F-20

Mine-Incident Report F-21

TRAINING F-21

Individual Training F-21

Leader Training F-22

Unit Training F-23

APPENDIX G. COUNTERMINE DATA G-l

BREACHING ASSETS VERSUS THREAT OBSTACLES G-l

FOREIGN MINE DATA G-l

FOREIGN MINEFIELD EMPLACEMENT DATA G-l

FOREIGN MINE DELIVERY SYSTEMS G-l

APPENDIX H. METRIC CONVERSION CHART H-l

GLOSSARY Glossary-1

REFERENCES References- 1

INDEX Index-l

IX

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LIST OF ILLUSTRATIONS

Figures

Page

gure 1-1. Mine components 1-2

gure 1-2. Methods of actuating mines 1-3

gure 1-3. Types of fuses 1-4

gure 1-4. AH D incorporating a release mechanism 1-7

gure 1-5. AHD not attached to the mine 1-7

gure 1-6. Hand-emplaced US AHDs 1-8

gure 2-1. Tactical versus protective obstacles 2-6

gure 2-2. Tactical -obstacle effects 2-6

gure 2-3. Minefield variables 2-7

gure 2-4. Vehicle mine encounter probability versus minefield density 2-9

gure 2-5. Disrupt-effect group 2-10

gure 2-6. Fix-effect group 2-11

gure 2-7. Turn-effect group 2-12

gure 2-8. Block-effect group 2-13

gure 2-9. Obstacle zones 2-16

gure 2-10. Obstacle belts 2-17

gure 2-11. Obstacle groups 2-18

gure 2-12. TF defenseCOA 2-24

gure 2-13. TF direct-fire analysis 2-25

gure 2-14. TF obstacle-intent integration and priorities 2-26

gure 2-15. Obstacle-plan refinement 2-28

gure 2-16. Scheme-of-obstacleoverlay 2-30

gure 2-17. Sample obstacle-execution matrix 2-31

gure 2-18. M inefield siting 2-38

gure 2-19. Exampleof minefield resourcing 2-40

gure 2-20. M ine resupply 2-41

gure 2-21. Supply-point resupply method 2-46

gure 2-22. Service-station resupply method 2-47

gure 2-23. Tailgate resupply method 2-48

gure 2-24. M inefield marking 2-51

gure 2-25. Marking of minefields and obstacle groups 2-52

gure 2-26. Sample obstacle-turnover work sheet 2-54

gure 3-1. AP SCATMINEs 3-2

gure3-2.ATSCATMINE 3-3

gure 3-3. Emplacement of ADAMs and RAAMs 3-11

gure 3-4. Gator SCATMINE system 3-15

gure 3-5. Gator minefield 3-17

gure 3-6. Volcano mine system 3-18

gure 3-7. Volcano components 3-18

gure 3-8. Volcano disrupt and fix minefields 3-21

gure 3-9. Volcano turn and block minefields 3-22

gure 3-10. MOP MS 3-22

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gure 3-11. MOPMS emplacement and safety zone 3-23

gure3-12. MOPMS in a disrupt minefield 3-25

gure 3-13. MOPMS in a fix minefield 3-26

gure 3-14. Ground Volcano minefield 3-27

gure 4-2. M18A1 claymore 4-2

gure 4-3. SLAM 4-3

gure 4-4. SLAM in bottom-attack mode 4-4

gure 4-5. SLAM in side-attack mode 4-5

gure 4-6. SLAM in timed-demolition mode 4-5

gure 4-7. SLAM in command-detonation mode 4-5

gure 4-8. M 93 Hornet 4-6

gure 4-9. Hornet reinforcing a conventional minefield 4-9

gure 4-10. Hornet reinforcing a Volcano minefield 4-10

gure 4-11. Hornet area-disruption obstacle 4-11

gure 4-12. Hornet gauntlet obstacle (one cluster) 4-12

gure 4-13. Hornet gauntlet obstacle (platoon) 4-13

gure 4-14. Hornet-enhanced turn-and fix-obstacle groups 4-14

gure 5-1. AT mines 5-1

gure 5-2. AP mines 5-3

gure 5-3. Prong-activated AP mine 5-5

gure 5-4. Trip-wire-activated AP mine 5-5

gure 5-5. Buried mine with pressure plate 5-6

gure 5-6. Buried mine with tilt rod 5-7

gure 5-7. Buried and concealed mines 5-7

gure 6-1. M inefield requirements computation work sheet 6-5

gure 6-2. Step-by-step procedures for completing the minefield requirements

computation work sheet 6-9

gure 6-3. Site layout 6-19

gure 6-4a. Laying a minefield 6-20

gure6-4b. Laying a minefield (continued) 6-21

gure 6-5. Laying an IOE short row 6-21

gure 6-6. Sample strip feeder report 6-22

gure 6-7. Laying a row minefield 6-23

gure 6-8. Measuring distances between mines with sandbags 6-25

gure 6-9a. Sample DA Form 1355 for a row minefield (front) 6-26

gure 6-9b. Sample DA Form 1355 for a row minefield (back) 6-27

gure 6-10. Standardized disrupt and fix row minefields 6-28

gure 6-11. Standardized turn row minefield 6-30

gure 6-12. Standardized block row minefield 6-32

gure 6-13. Site layout 6-35

gure 7-1. M inefield layout 7-2

gure 7-2. Cluster compositions 7-3

gure 7-3. Arrangement of clusters in a mine strip 7-3

gure 7-4. IOE baseline with short strips 7-4

gure 7-5. Clusters on an IOE short strip 7-7

gure 7-6. M inefield lanes and gaps 7-8

gure 7-7. M i ne-empl acement procedures 7-11

gure 7-8. Laying and fusing mines 7-14

gure 7-9. Lane closure 7-16

XI

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Page

igure8-l. Conventional minefield/munition field reporting chain 8-2

igure 8-2a. Sample DA Form 1355 (front side) for a standard-pattern

minefield/munition field 8-5

igure 8-2b. Sample DA Form 1355 (inside) for a standard-pattern

minefield/munition field 8-6

igure 8-2c. Sample DA Form 1355 (back side) for a standard-pattern

minefield/munition field 8-7

igure 8-3a. Sample DA Form 1355 (front side) for a Hornet minefield/munition field 8-12

igure 8-3b. Sample DA Form 1355 (back side) for a Hornet minefield/munition field 8-13

igure 8-4. Sample DA Form 1355-1-R 8-18

igure 8-5. Hasty protective row minefield/munition field record 8-19

igure 8-6a. Sample DA Form 1355 (front side) for a nuisance minefield/munition field 8-21

igure 8-6b. Sample DA Form 1355 (inside) for a nuisance minefield/munition field 8-22

igure 8-7. Scatterable minefield/munition field report and record work sheet 8-23

igure 8-8. Sample SCATM IN WARN 8-24

igure 8-9. Scatterable minefield/munition field report and record

for an ADAM/RAAM artillery mission 8-24

igure 8-10. Sample SCATM I N WARN for an artillery mission 8-25

igure 8-11. M inefield/munition field overlay symbols 8-26

igure 9-1. SampleOBSTINTEL report 9-3

igure 10-1. AN/PSS-12 mine detector 10-3

igure 10-2. ASTAM I DS 10-4

igure 10-3. IVMMD components 10-5

igure 10-4. Ml CLIC 10-8

igure 10-5. AVLM 10-8

igure 10-6. MICLIC employment in a minefield less than 100 meters deep 10-10

igure 10-7. MICLIC employment in a minefield of uncertain depth

or greater than 100 meters 10-10

gure 10-8. Skip zone 10-11

gure 10-10. APOBS 10-13

gure 10-11. Bangalore torpedo 10-13

gure 10-12. Skim technique 10-15

gure 10-13. MCB 10-15

gure 10-14. Mine-blade width compared to track-vehicle widths 10-16

gure 10-15. MCR 10-17

gure 10-16. Mine-roller width compared to track-vehicle widths 10-17

gure 10-17. Panther 10-19

gure 10-18. MiniFlail 10-20

gure 10-19. Grizzly 10-20

gure 10-20. CEV with mine rake 10-21

gure 10-21. Tripod 10-23

gure 10-22. 1 nitial lane marking 10-28

gure 10-23. 1 ntermediate lane marking 10-30

gure 10-24. Full lane marking 10-32

gure 10-25. Marking devices 10-35

gure 10-26. NATO standard marker 10-37

gure 10-27. NATO lane-marking conversion 10-37

gure 10-28. NATO standard marking for limited visibility 10-38

gure 11-1. 1 BASIC 11-6

XII

C3

Page

gure 11-2. Platoon-size sweep team 11-9

gure 11-3. Squad-size sweep team 11-10

gure 11-4. Sweep teams in echelon 11-11

gure 11-5. Linear clearance method 11-12

gure 11-6. Combat clearance method 11-13

gure 11-7. Deliberate route clearance 11-14

gure 11-8. Hasty route clearance 11-15

gure 11-9. Area clearance site layout 11-19

gure 11-10. Sampleenemy obstacle report 11-24

gure 11-11. Sample route status report 11-25

gure 11-12. Sample mine incident report 11-26

gure 12-1. Outrigger techniques 12-3

gure 12-2a. Sample DA Form 1355 (front side) for river mining 12-4

gure 12-2b. Sample DA Form 1355 (inside) for river mining 12-5

gure 12-3. Building sketch and mine plan (DA Form 1355) 12-7

gure 12-4. U nderground passageway 12-8

gure 12-5. Open spaces 12-8

gure 12-6. Street obstacles 12-9

gure 12-7. Roof obstacles 12-9

gure 12-8. Building obstacles 12-10

gure 12-9. Probable M MAP mine emplacement 12-11

gure 12-10. Probable M 16 AP mine emplacement 12-11

gure 12-11. Probable M 18A1 AP mine emplacement 12-12

gure 12-12. AT mine emplacement in urban areas 12-13

gure 12-13. AT mine emplacement in industrial and transportation areas 12-13

gure 12-14. ADAM/RAAM employment 12-14

gure 12-15. M OPM S employment 12-16

gure 13-1. Typical electric and nonelectric booby traps 13-6

gure 13-2. Methods of actuation 13-7

gure 13-3. Remotely connected traps 13-7

gure 13-4. Standard booby-trap sign 13-9

gure 13-5a. Sample DA Form 1355 (front side) for a booby-trapped area 13-12

gure 13-5b. Sample DA Form 1355 (inside) for a booby-trapped area 13-13

gure 13-6. 1 mprovised electrical FDs 13-24

gure 13-7. Improvised nonelectric FDs (shear-pin operated) 13-25

gure 13-8. 1 mprovised nonelectric FDs (spring-operated) 13-25

gure 13-9. 1 mprovised, electric delay devices 13-26

gure 13-10. 1 mprovised, nonelectric delay devices 13-26

gure 13-11. Typical punjis 13-27

gure 13-12. Side-closing trap 13-27

gure 13-13. Spike board 13-28

gure 13-14. Venus fly trap 13-28

gure 13-15. HE, artillery-shell AT device 13-30

gure 13-16. Platter charge 13-31

gure 13-17. 1 mprovised claymore device 13-32

gure 13-18. Grapeshot AP device 13-33

gure 13-19. Barbwire AP device 13-33

gureA-1. M14AP mine A-2

gureA-2. M22 wrench A-3

gureA-3. M14 minein ARMED position A-4

gure A-4. Removal of safety clip A-4

XIII

C2

Page

gure A-5. Bottom view of M 14 mine A-5

gureA-6. M16A1AP mine A-6

gure A-7. M16A1 mineand M25 wrench A-7

gureA-8. M 605 fuse A-8

gureA-9. Safety pins A-9

gure A-10. Buried mine with a trip wire A-9

gure A-ll. Metal collar on an M605 fuse A-10

gureA-12. M15AT mine A-12

gureA-13. M 20 wrench A-13

gure A-14. Correct safety-pin configuration A-14

gureA-15. Greasing the M 624 fuse A-14

gure A-16. Tightening the fuse with the extension rod A-15

gureA-17. M15 mine in the hole A-15

gure A-18. Extension-rod assembly A-16

gure A-19. Assembly of the extension rod into the fuse ring A-16

gure A-20. Removal of safety pin A-17

gure A-21. ARMED position A-18

gureA-22. SAFE position A-18

gureA-23. Safety fork A-19

gure A-24. Clearance test A-20

gureA-25. M15 mine in the hole A-20

gureA-26. M19AT mine A-21

gure A-27. Removal of the pressure plate A-22

gure A-28. Firing pin A-23

gureA-29. M21AT mine A-25

gureA-30. M 607 fuse A-26

gureA-31. M 26 wrench A-26

gureA-32. Buried M21 mine A-27

gure A-33. Removing the band and the stop A-28

gureA-34. M5FD A-30

gureA-35. Arming the M 15 A-31

gureA-36. M142FD A-32

gureA-37. Ml activator A-34

gure B-l. SLAM components B-l

gure B-2. Hornet components B-3

gure B-3. Hornet controls and indicators B-4

gureC-1. GMZ armored tracked mine layer C-2

gureC-2. Threat-style rapidly emplaced minefield C-3

gure C-3. Threat-style antitrack minefield C-3

gureC-4. Threat-style anti hull minefield C-4

gureC-5. Threat-style AP minefield C-4

gureC-6. UMZSCATMINE system C-6

gureC-7. Chemical-mine employment C-7

gureC-8. BAT-M with BTU bulldozer blade C-8

gureC-9. KMT-4plow C-8

gureC-10. IMP portable mine detector C-9

gureC-11. DIM mine detector C-9

gureC-12. KMT-5 plow-roller combination C-10

gureC-13. 1 MR armored engineer tractor C-10

gureC-14. M1979 armored mine clearer C-ll

XIV

C3

Page

Figure D-l. Air Volcano system D-l

Figure D-2. Turn obstacle D-6

Figure D-3. Block obstacle D-7

Figure D-4. Disrupt obstacle D-7

Figure D-5. Fix obstacle D-8

Figure D-6. Site layout D-15

Figure D-7. Sample Volcano card D-17

Figure D-8. Fencing for an air Volcano minefield D-21

Figure E-l. M16AP mine E-6

Figure E-2. M18A1AP mine E-7

Figure E-3. M 15 and M19AT mines E-8

Figure E-4. M21 AT mine E-8

Figure E-5. Excerpt from Risk-Assessment Techniques Manual, prepared by the

Department of Transportation's Transportation Safety Institute, August 1986 E-9

Figure E-6. Preliminary hazard-analysis work sheet (arming M15) E-ll

Figure E-7. Preliminary hazard-analysis work sheet (disarming M15) E-12

Figure E-8. Preliminary hazard-analysis work sheet (arming M16) E-13

Figure E-9. Preliminary hazard-analysis work sheet (disarming M16) E-14

Figure E-10. Preliminary hazard-analysis work sheet (arming M19) E-15

Figure E-ll. Preliminary hazard-analysis work sheet (disarming M19) E-16

Figure E-12. Preliminary hazard-analysis work sheet (arming M21) E-17

Figure E-13. Preliminary hazard-analysis work sheet (disarming M21) E-18

Figure E-14. Preliminary hazard-analysis work sheet (command detonation) E-19

Figure E-15. Preliminary hazard-analysis work sheet (peripheral factors) E-20

Figure F-l. AN/PSS-12 metallic mine detector F-4

Figure F-2. AN/PSS-12 packed components F-4

Figure F-3. Electronic unit F-5

Figure F-4. Battery installation F-5

Tables

Table2-1. Echelons of obstacle control and effect 2-15

Table 2-2. Planning factors for the mine dump 2-21

Table 2-3. Planning factors for work rates 2-21

Table 2-4. Planning factors for standardized row minefields 2-22

Table 2-5. Planning factors for scatterable minefields 2-22

Table 2-6. Ranges of common weapons 2-23

Table 2-7. Personnel requirements for a Class IVA/ supply point 2-42

Table 2-8. Class IVA/ haul capacity 2-45

Table 3-1. Characteristics of AP SCATMINEs 3-2

Table 3-2. Characteristics of AT SCATM IN Es 3-4

Table 3-3. SD windows 3-7

Table 3-4. Emplacement authority 3-9

Table 3-5. Coordination responsibilities 3-10

Table 3-6. RAAM and ADAM minefield density and size 3-14

Table 3-7. Marking scatterable minefields 3-26

Table 3-8. Safety and fragment hazard zones 3-28

Table4-1. Hornet minimum emplacement distances 4-15

xv

C3

Page

Table 5-1. Characteristics of AT mines 5-2

Table 5-2. Characteristics of AP mines 5-3

Table 5-3. Sympathetic detonation chart 5-8

Table 7-1. Platoon organization and equipment 7-10

Table 7-2. Sample mines tally sheet 7-15

Table 8-1. Minefield/munition field obstacle numbering system 8-8

Table 8-2. Abbreviations for obstacletypes 8-9

Table 9-1. Lane widths 9-4

Table 10-1. Lane-marking levels, unit responsibilities, and trigger events 10-33

Table 10-2. Guidelines for lane-marking devices 10-34

Table 11-1. Sample task organization for a route clearance 11-2

Table 11-2. Personnel and equipment requirements for a sweep team 11-8

Table 11-3. Sampletask organization for an area clearance 11-17

Table 13-1. Tactical reports 13-11

Table 13-2. Clearing equipment 13-17

TableC-1. Normal parameters for threat-style minefields C-2

Table D-l. Air Volcano capabilities and limitations D-4

Table D-2. Air Volcano minefield data D-6

Table D-3. Planning process (H-hour sequence) D-ll

Table D-4. Air Volcano dispensing times based on air speed D-19

Table E-l. Mine color-coding system E-2

Table F-l. Risk-assessment criteria F-18

Table F -2. Sample risk assessment F-19

TableG-1. Mounted breaching assets versus threat obstacles G-2

TableG-2. Dismounted breaching assets versus threat obstacles G-5

TableG-3. Foreign track-width AT mines G-9

TableG-4. Foreign full-width AT mines G-10

TableG-5. Foreign side-attack AT mines G-ll

TableG-6. Foreign pressure-fused AP mines G-ll

TableG-7. Foreign trip-wire/break-wire-fused AP mines G-12

TableG-8. Foreign emplaced minefields G-13

Table G-9. Foreign mine delivery systems G-14

Table H-l. Metric conversion chart H-l

XVI

C2

Preface

Field Manual (FM) 20-32 provides United States (US) armed forces with tactical, technical, and
procedural guidance for conducting mine and countermine operations. It applies toall elements of
the combined arms team for maneuver and engineer staff planning and coordination. The manual
is presented in three parts— mine operations, counteroperations, and special -mining operations.

The guidance provided focuses on individual skills of emplacing and removing mines, team and
squad tasks, platoon and company organization and planning, and battalion/task force (TF)
organization and coordination for successful obstacle reduction and breaching operations.

The provisions of this publication support existing doctrine established by FMs 5-34, 5-100, 90-7,
and 90-13-1. It also contains new and improved techniques for emplacing row mines; marking,
reporting, and recording minefields; reducing simple and complex obstacles; and emplacing a
standard-pattern minefield. This manual reflects new doctrine from FMs 5-10, 5-71-2, and 5-71-3.

This publication implements the following I nternational Standardization Agreements
(STANAGs) between North Atlantic Treaty Organization (NATO) forces:

• STAN AG 2036. Land Minefield Laying, Marking, Recording, and Reporting Procedures.
Edition 5.

• STAN AG 2889. Marking of H azardous Areas and Routes Through Them. Edition 3.

• STAN AG 2990. Principles and Procedures for the Employment in Land Warfare of
Scatterable Mines with a Limited Laid Life. Edition 1.

NOTE: US policy regarding the use and employment of antipersonnel land mines
(APLs) outlined in this FM is subject to the Convention on Certain Conventional
Weapons and Executive Orders. Current US policy limits the use of non-self-
destructing APLs to (1) defending the US and its allies from armed aggression across
the Korean demilitarized zone and (2) training personnel engaged in demining and
countermine operations. The use of the M18A1 claymore in the command-detonation
mode is not restricted under international law or Executive Order.

All references to US employment of non-self-destructing APLs (such as row mining) in this
manual are intended to provide doctrine for use in Korea only. This information is provided in
bold lettering throughout the manual. Detailed doctrine on APLs is also provided to ensure that
U S forces recognize how the enemy can employ these weapons.

As the US military seeks to end its reliance on APLs, commanders must consider the increased
use of other systems such as the M 18A1 claymore, nonlethal barriers (such as wire obstacles),
sensors and surveillance platforms, and direct and indirect fires.

This publication includes the following appendixes:

• Appendix A. Installation and Removal of US Mines and Firing Devices.

• Appendix B. Controls and Components of Special-Purpose Munitions.

• Appendix C. Threat Mine/Countermine Operations.

• Appendix D. Air Volcano.

• Appendix E. Safety and Training.

• Appendix F. Mine Awareness.

• Appendix G. Countermine Data.

• Appendix H. Metric Conversion Chart.

XVII

The proponent for this publication is Headquarters, US Army Training and Doctrine Command
(TRADOC). Forward comments and recommendations on Department of the Army (DA) Form
2028 to Commandant, US Army Engineer School, ATTN: ATSE-DME-MWF, Fort Leonard Wood,
Missouri 65473-5000.

Unless this publication states otherwise, nouns and pronouns do not refer exclusively to men.

XVII

Chapter 1

Introduction

This chapter provides the mechanics and characteristics of antitank (AT)
mines and munitions, antipersonnel (AP) mines and munitions, and
anti handling devices (AHDs). The information contained in this chapter
also provides a foundation for the rest of the manual.

Land-based mines and munitions are hand-emplaced, remote-delivered,
ground-delivered, or air-delivered:

• Hand-emplaced mines and munitions require manual arming and
are labor-, resource-, and transport-intensive.

• Remote- and air-delivered mines and munitions require less time
and labor; however, they are not as precisely placed as hand-
emplaced mines and munitions.

• Ground-delivered mines are less resource-intensive than hand-
emplaced mines. They are not precisely placed; however, the
minefield boundaries are.

Soldiers can surface lay or bury mines and munitions and can place AHDs
on hand-emplaced AT mines.

NOTE: Some countries employ AHDs on AP mines, but US forces
are not authorized to employ AHDs on any type of AP mine.

MECHANICS OF MINES

Characteristics and Functioning

A land mine is an explosive device that is designed to destroy or damage
equipment or personnel. Equipment targets include ground vehicles, boats,
and aircraft. A mine is detonated by the action of its target, the passage of
time, or controlled means. There are two types of land-based mines— AT and
AP. Mines generally consist of the following parts (Figure 1-1, page 1-2):

Firing mechanism or other device (sets off the detonator or igniter
charge).

Detonator or igniter (sets off the booster charge).

Booster charge (may be attached to the fuse or the igniter or be part of
the main charge).

Main charge (in a container; usually forms the body of the mine).

Casing (contains all the above parts).

Introduction 1-1

FM 20-32

=«^i

.czzzrf:

Firing mechanism

Casing

charge

3?

> * r > r > > t ft

Booster charge
Detonator or igniter

Figure 1-1. Mine components

Components and Initiating Actions

A firing mechanism prevents the mine from exploding until it makes contact
with, or is influenced by, its target. Once a mine has been armed, the firing
mechanism may be actuated by the foil owing methods (Figure 1-2):

• Applying pressure (including tilt rod).

• Pulling a trip wire.

• Releasing tension or breaking a trip wire.
Releasing pressure.

• Passage of time (time-delay mechanism).
Impulses.

— Electrical.

— Vibration.

— Magnetic-influence.

— Electromagnetic-frequency

— Infra red-sensor ed.

— Acoustic.

To arm some mines, you must position the igniter, set the mechanism properly,
and disengage the safety device (usually by removing a safety pin). The fuse is
the initial component in the firing chain; it has a low-explosive (LE) powder
but is highly sensitive. The fuse is actuated by an initiating action. Although
mines are issued with a standard fuse, alternate fuses are issued separately
for some mi nes.

The four main fuse types are shown in Figure 1-3, page 1-4.

1-2 Introduction

FM 20-32

Pressure

*

^

V^s-^yw^/s*-.

Time-delay

Magnetic-influence

Electromagnetic-frequency

Figure 1-2. Methods of actuating mines

Introduction 1-3

FM 20-32

Mechanical. A spring drives a
striker against a percussion cap,
which fires the detonator.

Striker.

Striker spring
Percussion cap

Chemical. A small container of a
chemical compound is broken by
the initiating action. The chemical
compound reacts with another
substance to generate heat,
which ignites the detonator.

Restraining wire
Primer \ Chemical container

...—^-. \z^* 1 . . ■ *T\

Firing

Firing-pin spring

Friction. The initiating action
ignites substances inside the
fuse by friction. The flame fires
the detonator.

Chemical compound Delay charge

Trip wire

— *±- JM '■--■■■■- i - k ±±-jA.

Detonator

Plunger head

Contact rod

Electrical. The initiating action
closes an electrical circuit, which
functions an electrical detonator.

Contact

Electric detonator

Battery

Figure 1-3. Types of fuses

ANTITANK MINES

AT mines are designed to immobilize or destroy vehicles and their occupants.

Types of Kills

An AT mine produces a mobility kill (M -Kill) or a catastrophic kill (K-K ill). An
M-Kill destroys one or more of the vehicle's vital drive components (for

1-4 Introduction

C2, FM 20-32

example, breaks a track on a tank) and immobilizes the target. An M-Kill does
not always destroy the weapon system and the crew; they may continue to
function. In a K-K ill, the weapon system and/or the crew is destroyed.

Types of Sensing

AT fuses fall into three design categories:

• Track-width. Usually pressure-actuated, requiring contact with the
wheels or tracks of a vehicle.

• Full-width. Activated by several methods— acoustics, magnetic-
influence, tilt-rod, radio-frequency, infrared-sensored, command, or
vibration. Tilt-rod or magnetic-influence fuses are the most common.
Full-width fuses are designed to be effective over the entire target
width and can cause a K-Kill from penetration and spalling metal or
from secondary explosions. When a full-width fuse is activated solely
by contact with the wheels or tracks of the target vehicle, it usually
causes an M-Kill because most of the energy is absorbed by the wheels
or tracks.

• Off-route. Designed to be placed along the side of a route likely to be
taken by armored vehicles. It has numerous fuzing possibilities,
including infrared, seismic, break wire, and magnetic. It produces an
M-Kill or a K-Kill, depending on the location of the target at the time
of mine detonation.

Types of Warheads

AT mines can be identified by their warheads:

• Blast AT mines derive their effectiveness from the force generated by
high-explosive (HE) detonation. They usually produce an M-Kill when
the blast damages the track or the vehicle, but a K-Kill is also
possible.

• Shaped-charge mines use a directed-energy warhead. A shaped charge
is formed by detonating an explosive charge behind a cone of dense
metal or other material. Upon detonation, the cone collapses and
forms a metal slug and a gaseous metal jet that penetrate the target.
A K-Kill is probable if the crew or ammunition compartment is hit.

• Explosive-formed penetrating (EFP) mines have an explosive charge
with a metal plate in front. Upon detonation, the plate forms into an
inverted disk, a slug, or a long rod. A K-Kill is probable if the crew or
ammunition compartment is hit.

ANTIPERSONNEL MINES

Types of Kills

AP mines can kill or incapacitate their victims. The injuries and deaths they
cause commit medical resources, degrade unit morale, and damage
nonarmored vehicles. Some types of AP mines may break or damage the track
on armored vehicles.

Introduction 1-5

C2, FM 20-32

Types of Sensing

AP mines can be fused in many ways, to include pressure, seismic, wire, or
command detonation:

• Pressure fuses usually activate an AP mine when a load is placed on
the fuse.

• Seismic fuses activate an AP mine when the sensor detects vibrations.

• Trip wires or break wires activate an AP mine when something
disturbs barely visible wires.

• Command-detonated mines are activated by a soldier when he detects
the enemy in the mines' blast area.

Types of Effects

AP mines contain five types of effects:

Blast. Cripples the foot or leg of a soldier who steps on it; can also
burst thetires of a wheeled vehiclethat passes over it.

Bounding-fragmentation. Throws a canister into the air; the canister
bursts and scatters shrapnel throughout the immediate area.

Direct -fragmentation. Propels fragments in the general direction of
enemy soldiers.

Stake-fragmentation. Bursts and scatters shrapnel in all general
directions.

Chemical. Disperses a chemical agent to whoever activates it;
contaminates the surrounding area.

ANTIHANDLING DEVICES

AHDs perform the function of a mine fuse if someone attempts to tamper with
the mine. They are intended to prevent moving or removing the mine, not to
prevent reduction of the minefield by enemy dismounts. An AHD usually
consists of an explosive charge that is connected to, placed next to, or
manufactured in the mine. The device can be attached to the mine body and
activated by a wire that is attached to a firing mechanism. US forces can
employ AHDs on conventional AT mines only. Other countries employ AHDs
on AT and AP mines.

Some mines have extra fuse wells that make it easier to install AHDs (Figure
1-4). An AHD does not have to be attached to the mine; it can be placed
underneath the mine (Figure 1-5). Mines with AHDs are sometimes
incorrectly called booby-trapped mines.

1-6 Introduction

C2, FM 20-32

... ■■><.\;»J»i .,■$.«& <;if,; .,

Secondary
fuse well

urwjkm ' AW/JAW W/&SX7.

Activator
M5 pressure-release FD

Figure 1-4. AHD incorporating a release mechanism

M142 multipurpose ^
FD (pressure-release
model)

C4 explosive

Detonating cord

Blasting cap

Figure 1-5. AHD not attached to the mine

The following hand-emplaced AHDs are used by US forces (Figure 1-6, page 1-8):

• M5 pressure-release firing device (FD).

• M 142 multipurpose FD.

These devices use a spring-loaded striker with a standard base, and they
function in one or more modes— pressure, pressure-release, tension, and/or
tension-release. When an FD is employed as an AHD on certain AT mines, it
requires the use of an Ml or M 2 activator. FDs and activators are described in
Appendix A.

Introduction 1-7

FM 20-32

M5 Pressure-Release FD

Tension-release
device

Round-head safety pin

Positive safety
(remove last)

Square-head safety pin

M142 Multipurpose FD

Figure 1-6. Hand-emplaced US AHDs

1-8 Introduction

PART ONE

Mine Operations

This part of the manual provides tactical and technical information on mines,
minefields, and mine-delivery systems; emplacement and employment methods and
responsibilities; and reporting and recording procedures for US mine operations.
Current US policy for restrictions on AP mines and other devices is also discussed.

Chapter 2

Mine-Warfare Principles

This chapter provides guidance to staff personnel who must plan the
employment of minefields for tactical operations. It defines the four types
of minefields— protective, tactical, nuisance, and phony. The remainder of
the chapter provides guidance on the employment of tactical minefields—
specifically their functions, designs, and integration principles.

MINE-WARFARE CONCEPTS

Mines are explosive devices that areemplaced to kill, destroy, or incapacitate
enemy personnel and/or equipment. They can be employed in quantity within
a specified area to form a minefield, or they can be used individually to
reinforce nonexplosive obstacles. They can also beemplaced individually or in
groups to demoralize an enemy force. A minefield is an area of ground that
contains mines or an area of ground that is perceived to contain mines (a
phony minefield). Minefields may contain any type, mix, or number of AT and/
or AP mines. Minefields are used to —

Produce a vulnerability on enemy maneuver that can be exploited by
friendly forces.

Cause the enemy to piecemeal his forces.

I nterfere with enemy command and control (C 2 ).

Inflict damage to enemy personnel and equipment.

Exploit the capabilities of other weapon systems by delaying enemy
forces in an engagement area (EA).

Protect friendly forces from enemy maneuver and infiltration.
TYPESOF MINEFIELDS

There are four general types of minefields— protective, tactical, nuisance, and
phony. Each type is determined by its distinct battlefield purpose. Therefore,

Mine-Warfare Principles 2-1

C2, FM 20-32

minefields are employed differently, and they target the enemy in unique
ways that support the overall concept of the operation.

• Protective minefields are employed to protect soldiers, equipment,
supplies, and facilities from enemy attacks or other threats.

• Tactical minefields directly effect the enemy's maneuver in a way that
gives the defending force a positional advantage.

• Nuisance minefields impose caution on enemy forces and disrupt,
delay, and sometimes weaken or destroy follow-on echelons.

• Phony minefields deceive the enemy about the exact location of real
minefields. They cause the attacker to question his decision to breach
and may cause him to expend his reduction assets wastefully Phony
minefields may be employed in conjunction with other minefields, but
should be used only after the enemy has become mine-sensitive.

It is important to distinguish the difference between the types of minefield
and the means of emplacement. Volcano, Modular Pack Mine System
(MOP MS), standard-pattern, and row mining are not types of minefields; they
are just some of the means used to empl ace tactical, nuisance, and protective
minefields. They may also be the method of emplacement that is replicated by
a phony minefield.

Protective Minefields

Protective minefields are employed to protect soldiers, equipment, supplies,
and facilities from enemy attacks or other threats. Other threats range from
enemy surveillance to theft of supplies and equipment. In tactical operations,
protective minefields provide friendly forces with close-in protection and
defeat the enemy's ability to maneuver or utilize the tenants of offense. They
deny mechanized penetration and dismounted infiltration. In military
operations other than war (MOOTW), protective minefields may focus on
preventing unauthorized access to facilities and installations, rather than
assisting in the destruction of an enemy force.

Protective minefields are usually employed and emplaced at the small-unit
level (platoon or company/team). The authority to emplace protective
minefields is normally delegated to the company/team commander. In some
cases, such as a hasty defense, protective minefields are laid on short notice by
units that use mines from their basic load or local stock. More commonly,
protective minefields are used as part of a unit's deli berate defense. The mines
are laid so that they are easy to detect and recover by the laying unit.

An important aspect of protective minefields is the requirement to recover
them before leaving the area. This is often overlooked and is difficult to
control because they are emplaced at the small-unit level. When a unit is
being relieved in place by an adjacent unit, protective minefields are turned
over to the relieving unit (minefield turnover is further defined later in this
chapter). The decentralized emplacement of protective obstacles makes
consolidating reports and records difficult and requires command
involvement.

Much like final protective fires (FPF), protective minefields provide the
defender with close-in protection during the enemy's final assault. Protective
minefields serve two purposes. First, they impose a delay on an attacker that

Mine-Warfare Principles 2-2

C2, FM 20-32

allows the defender time to break contact as the unit displaces to another
battle position. Secondly, they break up the enemy's assault to complete its
destruction. The composition of a protective minefield is driven by the
vulnerability of the defender:

• Dismounted infantry is the greatest close-combat threat to a
defending tank company/team. Protective minefields encountered in
this case consist predominantly of AP mines that limit enemy
dismounts from closing with the armor defender.

• A tank force is the greatest threat to an infantry defense. Protective
minefields in this case consist predominantly of AT mines that reduce
the enemy's ability to close quickly onto the infantry's position.

Neither AP nor AT mines are used in isolation. The preponderance of mine
composition is designed against the most severe close-combat threat and the
likelihood of that threat.

A protective minefield may take many forms. It may be only a few mines in
front of a platoon, or it may be a standard-pattern minefield around an
airfield. Protective minefields are used in both close and rear operations, and
they are classified as either hasty or deliberate:

• Hasty protective minefields are temporary in nature and are used as
part of a unit's defense peri meter. They are usually laid by units using
mines from their basic load. If time permits, mines should be buried to
increase their effectiveness; but they can be laid on top of the ground.
AHDs and low-metallic mines are not used so that the minefield can
be easily recovered. Mines are employed outside the hand-grenade
range but within the range of small-caliber weapons. All mines are
picked up by theemplacing unit upon leaving the area, unless enemy
pressure prevents mine retrieval or the minefield is being transferred
to a relieving commander. The brigade commander has the initial
authority to employ hasty protective minefields. This authority may
be delegated to a battalion or company commander on a mission basis.
Procedures for emplacing a hasty protective row minefield are
contained in Chapter 6.

• Deliberate protective minefields are more permanent, require more
detailed planning, and usually require more resources. They are
commonly used to protect static assets (vital sites) — logistical sites,
communication nodes, depots, airfields, missile sites, air-defense
artillery (ADA) sites, and permanent-unit locations. A typical
deliberate protective minefield is the standard-pattern minefield;
however, a row minefield can also be used. Deliberate protective
minefields are usually emplaced for extended periods of time and can
be transferred to another unit. Techniques for emplacing deliberate
protective minefields are discussed in Chapters 6 and 7.

Tactical Minefields

Tactical minefields are employed to directly attack enemy maneuver and to
give the defender a positional advantage over the attacker. Tactical minefields
may be employed by themselves or in conjunction with other types of tactical
obstacles. They attack the enemy's maneuver by disrupting its combat

Mine-Warfare Principles 2-3

C2, FM 20-32

formations, interfering with its C 2 , reducing its ability to mass fires, causing
him to prematurely commit limited breaching resources, and reducing his
ability to reinforce. The defender masses fires and maneuver to exploit the
positional advantage created in part by tactical obstacles.

Tactical minefields add an offensive dimension to the defense. They are a
commander's tool for recapturing and maintaining the initiative that is
normally afforded to an attacker. Combined with fires, tactical obstacles force
the attacker to conform to the defender's plan.

Tactical minefields may be emplaced during offensive operations to protect
exposed flanks, isolate the objective area, deny enemy counterattack routes,
and disrupt enemy retrograde. This chapter further discusses the principles
behind designing, integrating, siting, and emplacing tactical minefields.

Nuisance Minefields

Nuisance minefields area form of tactical minefields. They are mainly used to
impose caution on enemy forces and to disrupt, delay, and sometimes destroy
follow-on echelons. Once nuisance minefields are emplaced, they do not
require cover by observation or direct fire. Nuisance minefields are usually
irregular in size and shape; they can be a single group of mines or a series of
mined areas. They can be used to reinforce existing obstacles and can also be
rapidly emplaced on main avenues of approach (AAs). Conventional mines
and scatterable mines (SCATMINEs) may be used in nuisance minefields.

Phony Minefields

Phony minefields are areas of ground that are altered to give the same
signatureasa real minefield and thereby deceive the enemy. Phony minefields
serve two primary functions. First, they confuse an attacker's breach cycle and
cause him to question his breach decision. Secondly, they may cause an
attacker to wastefully expend reduction assets to reduce mines that are not
really there.

The success of phony minefields depends on the enemy's state of mind. The
bluff succeeds best when the enemy is mine-conscious and has already
suffered the consequences of a mine encounter. A fear of mines can quickly
evolve into paranoia and break the momentum of the enemy's attack.
Therefore, phony minefields are normally employed in conjunction with real
minefields and are seldom employed alone. Once the enemy has become mine-
conscious, phony minefields may produce considerable tactical effects with
very little investment in time, labor, and material. Phony minefields may also
be used to extend the front and depth of live minefields when mines or labor
are in short supply or when time is restricted. They may be used to conceal
minefield gaps through live minefields. There is no guarantee that phony
minefields will achieve their purpose.

There are two mission-essential tasks inherent in the employment of a phony
minefield:

• The phony minefield must completely replicate a live minefield in
every detail, using a specific method of emplacement as a model. This
becomes the deception story, and every aspect of the phony minefield
must support the deception story. For example, if the deception story is

Mine-Warfare Principles 2-4

C2, FM 20-32

a buried row minefield, the depth, front, and marking must be similar
to that of a live buried row minefield. The ground should be disturbed,
and tracks should be made on the ground in the same pattern as other
minefields to give the ground the same signature. Occasional empty
mine crates, discarded fuses, or other mine-laying supplies add to the
deception.

• The deception story must never be compromised. Once emplaced, the
phony minefield must be regarded by friendly forces as live until the
tactical situation no longer warrants maintaining the deception. This
can be extremely painful for the friendly unit. There is great
temptation to drive through, rather than around, a known phony
minefield— particularly if it is intended to be a gap between live
minefields. However, one vehicle driving through a phony minefield
and observed by enemy reconnaissance compromises the minefield's
effectiveness.

Live mines are never laid in a phony minefield. A minefield designated as
phony implies that the area contains no live mines. Emplacing even a single
live mine within a phony minefield makes it a live minefield. Empty tins and
such may be laid in a phony minefield but is seldom worthwhile. Minefield
marking and covering fire should be the same as for a live minefield.
E mployment authority and reporting requirements are the same as for the
minefield being simulated.

PROTECTIVE VERSUS TACTICAL MINEFIELDS

As discussed, minefields can be tactical or protective obstacles (Figure 2-1,
page 2-6). Tactical and protective obstacles have different purposes with
regard to the enemy's maneuver. This difference causes them to have a
particular relative place on the battlefield. Tactical obstacles attack enemy
maneuver and are placed on the battlefield where the enemy maneuvers from
march, prebattle, and attack formations. Protective obstacles are used to
protect the force from the enemy's final assault onto the force's position.
Protective obstacles are close to defensive positions and are tied in with the
FPF of the defendi ng unit. Additional information on obstacles can be found in
FM 90-7.

TACTICAL MINEFIELDS

Tactical minefields are designed, sited, emplaced, and integrated with fires to
produce four specific tactical-obstacle effects— disrupt, turn, fix, and block
(Figure 2-2, page 2-6). Each obstacle effect has a specific impact on an enemy's
ability to maneuver, mass, and reinforce. Obstacle effects also increase the
enemy's vulnerability to friendly fires. They support the friendly scheme of
maneuver by manipulating the enemy in a way that is critical to the
commander's intent. Minefield design is the means by which an emplacing
unit varies minefield width, minefield depth, mine density, mine composition,
the use of AH Ds, and the irregular outer edge (IOE) to best achieve one of the
four tactical-obstacle effects. Modifying these variables is at the heart of
tactical minefield employment principles.

Mine-Warfare Principles 2-5

C2, FM 20-32

Enemy Enemy maneuver
assault phase

EA

Protective Tactical
obstacles obstacles

Figure 2-1. Tactical versus protective obstacles

Obstacle Effect

Application

Examples Conveying
Intent

Description

Disrupt

The short arrow
indicates where an
enemy is attacked by
obstacles. The longer
arrows indicate where
the bypass is allowed
and attacked by fires.

f^\

OG

Causes an enemy to
break up its formation
and tempo, interrupt its
timetable, commit its
reduction assets
prematurely, and
piecemeal the attack.

"*§

Turn ^V

1

The heel of the arrow is
the anchor point. The
direction of the arrow
indicates the desired
direction of turn.

-s? J&

Manipulates an enemy's
maneuver in a desired
direction.

Fix

The irregular part of the
arrow indicates where
an enemy advance is
slowed by obstacles.

Mh

%C-:}

Slows an enemy within
a specific area,
normally an EA. Gives
the defender time to
acquire, target, and
destroy the attacking
enemy throughout the
depth of an EA.

Block

The ends of the vertical
line indicate the limit of
an enemy's advance
and where obstacles tie
in to no-go terrain.

fl

veo Oc-

Stops an enemy along a
specific AA or prevents
it from passing through
an EA.

NOTES:

1. Arrows indicate the direction of enemy attack.

2. Minefields must be integrated with fires to achieve the desired effect.

Figure 2-2. Tactical-obstacle effects

Mine-Warfare Principles 2-6

C2, FM 20-32

Minefield Variables

First, it is important to understand how the variables relate to minefield
effects. Figure 2-3 clearly defines some of the terms used to discuss minefield
variables.

Assume
100 mines

• • • m • • • a
• • # •

Minefield
depth 100 m

Linear density
Area density:

Minefield front
200 m

/: 1 00 mines -=- 200 meters = 0.5 mine per meter of front
1 00 mines -=- (1 00 x 200) = 0.005 mine per square meter

Front

Depth

Density

Figure 2-3. Minefield variables

Minefield front is the dimension of a minefield that defines how much of the
attacking enemy formation is affected by the minefield. The front of a
minefield is based on the desired obstacle effect (disrupt, turn, fix, or block)
and the attack front of a company-size enemy force. The front of an attacking
enemy depends largely on the type of enemy force (armored, motorized, or
dismounted infantry) and norms by which the enemy army fights. For
armored warfare, the minefield front is based on effecting a doctrinal company
attack front of 500 meters (13 to 18 combat vehicles). For dismounted warfare,
the minefield front is based on effecting a company attack front of 150 meters.
The front may vary and require a study of enemy force and terrain. Groups of
individual minefields are employed to achieve a larger front for battalion and
larger enemy formations. For example, a battalion consisting of 52 to 72
combat vehicles has a front of 1,500 meters and requires more minefields.

Minefield depth is based on the amount of reduction assets that will be
required by an enemy to reduce a lane. The standard should start with 100
meters and increase in depth if denying the enemy the use of a mobility
corridor (MC) is the intent (turn or block).

Minefield density depicts the number of mines in a minefield. It is expressed
in linear or area density:

Mine-Warfare Principles 2-7

C2, FM 20-32

• Linear density is the average number of mines within a 1-meter-wide
path through the minefield's depth, anywhere along the front. I n
Figure 2-3, page 2-7, the minefield contains 100 mines, with a
minefield front of 200 meters. The linear density is 0.5 mine per meter
of front (100 mines/200 meters of front).

• Area density is the average number of mines within a square meter,
anywhere in the minefield. I n Figure 2-3, the minefield contains 100
mines within a 20,000-square-meter area. The area density is 0.005
mine per square meter (100 mines/[200 meters x 100 meters]). Area
density is normally used to express the density of scatterable
minefields.

Mine Composition

This variable includes the effective use of different types of mines. By using
full-width mines, the probability of kill increases for the minefield. AT mines
with AHDs (Korea Only: as well asAP mines) are used where the enemy is
expected to use dismounted reduction techniques.

Antitank Mines

If the enemy is an armored force, tactical obstacles are predominantly AT
mines. Track -width mines (M15s with the M 603 fuse) have a lower probability
of kill (M -Kill or K-Kill) than full-width mines (M 21s and M 15s with the M 624
fuse). The ratio of full-width versus track-width mines in a minefield depends
on the kill required. In general, a track-width minefield does not adequately
affect the enemy's maneuver.

Antipersonnel Mines

AP mines target dismounted soldiers. Their composition in tactical minefields
depends on the threat and the enemy's reduction assets. Based on current
technology, most breaching operations are accomplished by mechanical or
explosive means. (Korea Only: If the minefield group's intent is to
exhaust the enemy's breaching assets, AP mines should be integrated
to attack its dismounted reduction ability.)

Probabilities of Encounter and Kill

The probabilities of encounter and kill measure a minefield's lethality.

Probability of Encounter

The probability of encounter is measured by the chance (in percent) that a
vehicle, blindly moving through a minefield, will detonate a mine. The
probability of encounter is based on mine density, the type of mine, and the
type of enemy vehicle. I n short, the more dense a minefield, the higher the
probability is of encountering a mine. Probability of encounter also depends on
the fuse capability of the mines. Tilt-rod and magnetic-influence mines will
detonate if they are encountered anywhere along the width of the enemy
vehicle. Pressure-fused mines detonate if a vehicle's track or wheel actually
runs over them. The probability of encounter is also affected by the type of
enemy vehicle. The smaller the width or track signature of the vehicle, the
less likely it will encounter and detonate a mine.

Figure 2-4 illustrates the relationship between mine density and the
probability of encounter for light versus heavy tracked vehicles and for track-
width versus full-width mines. Figure 2-4 also provides general guidance for
varying the mine density to yield the necessary probability of encounter when
developing disrupt, fix, turn, and block minefields. Varying mine density is
further discussed later in this chapter.

Mine-Warfare Principles 2-8

FM 20-32

100-

o

CD
CL

3
O
O

o

CC
_Q
O

'*■?%'*?: Wirt l

■*.<■::■: :■••:■. .

TURN AND
BLOCK

1 2 3

Minefield linear density (mines per meter)

spill Pressure-fused mines (track-width)

HI Tilt-rod or magnetic-influence mines (full-width)

Figure 2-4. Vehicle mine encounter probability versus minefield density

Probability of Kill

The probability of kill is measured by the chance (in percent) that a vehicle
will no longer be mission-capable (M-Kill or K-K ill) because of mine effects. It
is a function of the combined probability that a vehicle will encounter a mine
and the probability that the mineeffect will produce an M-Kill or a K-K ill.

Antihandling Devices

Emplacing AHDs on mines is time-intensive. AHDs are added to a minefield
to discourage manual removal and reuse of mines by the enemy and to
demoral i ze the enemy who is attempti ng to reduce the mi nefi el d. AH Ds do not
prevent an enemy from reducing the minefield; they only discourage manual
reduction methods.

Irregular Outer Edge

An IOE is a strip/row or multiple strips/rows of mines that normally extend
toward the enemy from the first (enemy side) row of mines. An I OE is
employed to break up the otherwise regular pattern of a minefield. It is used
to confuse the enemy about the exact limits of the minefield, particularly its
leading edge. An IOE adds an unknown quality to a minefield that makes the
enemy's decision of whether to breach or bypass more difficult. The effect an
IOE has on enemy actions may increase the overall lethality of a minefield.

Mine-Warfare Principles 2-9

C2, FM 20-32

Design

Disrupt

Modifying minefield variables to achieve the desired obstacle effect is a
challenge for the engineer, both technically (resourcing and designing) and
tactically (supporting the maneuver scheme). Experience will provide the best
basis for designing minefields. Figures 2-5 through 2-8, pages 2-10 through 2-13,
provide guidelines for varying minefield depth, front, density, and composition
to best achieve disrupt, fix, turn, and block effects.

These are guidelines, not fixed rules. Minefield designs must be based
on a threat analysis. The designs are simply considerations or
parameters to use when designing tactical minefields, regardless of
the emplacement method. They apply to conventional mine-laying
techniques as well as the employment of SCATM I NE dispensers. These
parameters give the engineer the flexibility to design and emplace tactical
minefields based on mission, enemy, terrain, troops, time available, and
civilian considerations (METT-TC) (particularly resources and terrain) and
still achieve the required effect. These norms are also the basis for developing
minefield packages and emplacement procedures outlined throughout this
manual. Chapter 3 discusses the characteristics and emplacement procedures
for each of the SCATM I NE systems, Chapter 6 outlines procedures for row
mining using conventional mines, and Chapter 7 is dedicated to the standard-
pattern minefield. Each chapter describes standard disrupt, fix, turn, and
block minefield packages particular to that method of emplacement or
dispensing system.

Each tactical-obstacle effect has a specific resourcing factor. I n short, this
numeric value helps determine the amount of linear obstacle effort that is
needed to achieve the desired effect. The resource factor is multiplied by the
width of the AA or MC to get the total amount of linear obstacle effort
required. The linear obstacle effort is then divided by the minefield front norm
for the specific effect (rounded up) to yield the number of individual minefields
required in the obstacle group.

A disrupt effect (Figure 2-5) focuses fire planning and obstacle effort to cause
the enemy to break up its formation and tempo, interrupt its timetable,
commit reduction assets prematurely, and piecemeal the attack. It also
deceives the enemy about the location of friendly defensive positions,
separates combat echelons, or separates combat forces from their logistical
support. A disrupt effect should not be time-, manpower-, or resource-
intensive. It should not be visible at long range but easily detected as the
enemy nears it. Commanders normally use the disrupt effect forward of EAs.

Resource factor

0.5 (3 point obstacles) x AA

•
•
•

A

0.5

r

Group dimensions

W = 0.5 x AA

•
•
•

Probability of kill

50%

Minefield front

250 m

•
•
•

Minefield depth

100 m

AT mines

Yes (pressure/tilt)

AP mines

No (Korea Only: optional, based on
threat analysis)

i

AHD

Optional, based on threat analysis

IOE

No

Figure 2-5. Disrupt-effect group

2-10 Mine-Warfare Principles

Fix

FM 20-32

Normally, only half of the enemy's AA is attacked with minefields or other
tactical obstacles to achieve a disrupt effect. For a minefield to disrupt an
enemy company, half of the formation must react to the minefield. The typical
width of a disrupt-effect minefield is 250 meters with a standard minefield
depth of 100 meters. When designing a disrupt effect to attack an enemy
battalion, three disrupt-effect minefields are arrayed in a group to achieve a
width that is about half the size of the battalion's attack front (750 meters of
minefield). Multiply the resource factor of 0.5 by the width of the AA to
provide the amount of linear obstacle effort required for the disrupt effect.
When the AA is narrow, an alternative disrupt group is three point obstacles
along the AA.

Disrupt-effect minefields should be designed with approximately 50 percent
probability of mine encounter to achieve the desired disrupt effect (see Figure
2-4, page 2-9). They should contain predominantly track-width AT mines and
include full-width AT mines at the leading edge of the minefield to increase
the probability of mine encounter. This should cause the enemy to commit its
reduction assets.

AHDscan be added to disrupt-effect minefields to frustrate the enemy's
breaching and clearing operations. However, adding AH Ds may be too
resource-intensive for the return in effect. An IOE is not required.

A fix effect (Figure 2-6) focuses fire planning and obstacle effort to slow an
attacker within a specific area, normally an EA. The fix effect is primarily
used to give the defender time to acquire, target, and destroy the attacking
enemy throughout the depth of an EA or AA. A fix effect may be used to
generate the time necessary for the force to break contact and disengage as
the enemy maneuvers into the area (typically used for delays). Fix-effect
minefields in the obstacle group must be employed in depth, causing the
enemy formation to react and breach repeatedly. Fix-obstacle groups must
span the entire width of the AA. Commanders normally use the fix effect
insidetheEA.

Resource factor

1 .0 x AA

•
•
•

•
•
•

▲
1.0

Group dimensions

W = 1 .0 x AA

Probability of kill

50%

•
•
•

Minefield front

250 m

Minefield depth

120 m

•
•
•

AT mines

Yes (pressure/tilt)

•
•
•

•
•
•

▼

AP mines

No (Korea Only: optional, based on
threat analysis)

AHD

Optional, based on threat analysis

IOE

Yes

Figure 2-6. Fix-effect group

I ndividual fix-effect minefields must not appear too difficult to reduce. The
enemy should be enticed into the area. The concept is to employ multiple
minefields that individually attack a portion of a deploying company

Mine-Warfare Principles 2-11

FM 20-32

Turn

formation. Therefore, the fix-effect minefield front is 250 meters. It takes on
the characteristics of a disrupt- effect minefield with a similar density,
composition, and probability of encounter (Figure 2-4, page 2-9), with two
exceptions. First, AHDs are not used because the application of massed direct
and indirect fires complicate the enemy's breaching effort. Secondly, an IOE is
added to further delay the enemy and confuse the attacker on the exact
orientation of individual minefields. This also serves to increase the effective
lethality of the minefield. The majority of mines are track-width AT, but full-
width AT mines are used in the IOE and the leading edge of the minefield
because they are the most lethal.

While individual minefields are designed to attack only portions of an enemy
company formation, the fix-obstacle group is resourced, arranged, and sited to
attack the enti re front of an enemy battalion. Figure 2-6, page 2-11, depicts a
fix group effect on an attacking enemy battalion. I n this case, six fix-effect
minefields are arrayed in an area the full width of the battalion AA (1,500
meters) by 1,500 meters deep. Accordingly, the resource factor for a fix-effect
minefield group is one; the amount of linear minefield that should be
resourced equals the width of the AA.

A turn effect (Figure 2-7) manipulates the enemy's maneuver in a desired
direction. One technique or a combination of techniques aids in achieving the
turn effect. First, in order to entice the enemy to maneuver in the desired
direction rather than reduce the obstacle, the obstacle must have a subtle
orientation relative to the enemy's approach. Secondly, the obstacle and fires
must allow bypass in the direction desired by the friendly scheme of
maneuver. Obstacles in the start of the turn are visible and look more complex
than those in the direction of the turn. Finally, the obstacle is tied into
severely restricted terrain (restricted terrain as a minimum) at the initial
point of the turn. The point where the severely restricted terrain feature and
the minefield meet is known as the anchor point. Commanders normally use
the turn effect on the flanks of an EA.

Resource factor

1 .2 x AA

m

A

1.0

%

r

Group dimensions

W = 1 .0 x AA

Probability of kill

75%

Minefield front

500 m

Minefield depth

300 m

AT mines

Yes (pressure/tilt)

AP mines

No (Korea Only: optional, based on
threat analysis)

AHD

Optional, based on threat analysis

IOE

No

Figure 2-7. Turn-effect group

The standard turn-effect minefield has a width of 500 meters and a depth of
300 meters. One turn-effect minefield affects the entire width of an enemy
company's front. It must be deep enough to cause multiple applications of line-

2-12 Mine-Warfare Principles

Block

FM 20-32

charge reduction assets. I n short, the minefield must discourage any attempts
to breach and must entice the enemy to bypass rather than reduce. F igure 2-7
depicts a turn effect on an attacking battalion, with turn-effect minefields
arrayed in a group across a 1,500-meter AA. The angle of the minefields
should be subtle, encouraging the enemy to bypass individual minefields.
Each minefield overlaps another one to tie the minefields together and
prevent gaps. This is considered in the resource factor (1.2) for a turn-obstacle
group. This factor, multiplied by the width of the AA, equals the amount of
linear obstacle effort required for this turn effect.

As shown in Figure 2-4, page 2-9, turn-effect minefields must be extremely
lethal and achieve approximately 80 percent probability of encounter. I n other
words, an enemy vehicle attempting to reduce or pass through the minefield
will likely encounter a mine. This forces the small-unit commander to make
an immediate decision— breach or bypass. A lethal minefield that is covered
by intense fires and has an easily detectable bypass reduces breach decisions
to instinct and causes the enemy to choose the bypass (turn). To produce this
lethality, the majority of mines should be full-width AT. Full-width mines in
the first rows the enemy encounters and in the depth of the minefield either
exhaust the enemy's breaching assets or convince him to bypass early. AH Ds
are not required because the enemy force will seldom commit to dismounted
breach when faced with intense direct and indirect fires. An IOE should not be
used because the enemy must be able to determine the orientation of the
minefield and the bypass.

A block effect (Figure 2-8) integrates fire planning and obstacle effort to stop
an attacker along a specific AA or prevent him from passing through an EA.
Block obstacles are complex and are integrated with intense fires; they do not
stop an attacker by themselves. Individual block obstacles are employed
successively in a relatively shallow area. When the enemy reduces one block
obstacle, it is critical that he encounters another, thus denying him to project
combat power and maintain momentum. Block obstacles must defeat the
enemy's breaching effort (mounted and dismounted) as well as his maneuver.
A block effect must span the entire width of an AA and prevent a bypass.

Resource factor

2.4 x AA

•
•
•

•
i
•
•

A

1.0
1

f

Group dimensions

W = 1 .0 x AA

<

i
•

•
•

•

Probability of kill

80%

Minefield front

500 m

Minefield depth

300+ m

•

•
•
•

•

4
4
4

1 s
1 '

»

AT mines

Yes (pressure/tilt)

•
•
•

AP mines

No (Korea Only: Yes)

AHD

Yes

IOE

Yes

Figure 2-8. Block-effect group

The typical block-effect minefield is 500 meters wide and 300+ meters deep
(includes an IOE). Figure 2-8 depicts a block effect on an attacking battalion.
Note how individual minefields are arrayed to affect the entire width of the

Mine-Warfare Principles 2-13

FM 20-32

AA but in a relatively shallow depth. Eight block-effect minefields are
required in this example to achieve the necessary depth and width. The block
group is the most resource-intensive. A resource factor of 2.4 is multiplied by
the width of theAA to determine the linear obstacle effort required.

The lethality of a block-effect minefield (80 percent or higher) is similar to
that of a turn-effect minefield (see Figure 2-4, page 2-9). The lethality of the
group is considerably higher, si nee there are enough minefields in the group to
cover more than twice the width of the AA. This lethality is produced by a
density slightly greater than one mine per meter of front and the use of
predominantly full-width AT mines.

A block-effect minefield must be capable of defeating mechanical and
dismounted breach efforts. Therefore, AHDs (Korea Only: and AP mines)

are used to target dismounted breaching. An IOE confuses the attacker about
the exact minefield limits and complicates his employment of mechanical
reduction assets. The depth of the block-effect minefield requires employing
multiple line charges.

The above minefields are not standard solutions to every situation. The
terrain could dictate a decrease or an increase in the effort required.
Incorporating other reinforcing obstacles (AT ditches, road craters, wire,
SCATMINEs) aid in attacking the different reduction assets.

TACTICAL -OBSTACLE INTEGRATION PRINCIPLES

Tactical minefields are considered tactical obstacles and follow the same basic
integration principles. Tactical obstacle C 2 focuses on obstacle emplacement
authority and obstacle control.

Obstacle Emplacement Authority

Obstacle emplacement authority is the jurisdiction that a unit commander
has to emplace tactical obstacles. I n a theater of operations (TO), theater
commanders have the authority to emplace obstacles. I n most cases, they
delegate that authority to corps commanders who further delegate it to
division commanders. Division commanders then have obstacle emplacement
authority in their area of operations (AO), unless the authority is
subsequently withheld or restricted by a higher commander. Commanders
subordinate to corp and division do not have the authority to emplace
obstacles unless the higher commander delegates authority for a current
operation. Commanders use control measures and other specific guidance or
orders to grant obstacle emplacement authority to subordinate commanders.
Emplacement authority for SCATMINEs is covered in Chapter 3.

Obstacle Control

Commanders exercise obstacle control to ensure that obstacles support
current and future operations. Obstacle control ensures that subordinate
commanders emplace obstacles to best support the higher commander's
scheme of maneuver. It also ensures that subordinate commanders do not
interfere with future operations. Commanders maintain obstacle control by
focusing or withholding emplacement authority or by restricting the types or
locations of obstacles. Commanders use control measures, specific guidance,
and orders to maintain obstacle control.

2-14 Mine-Warfare Principles

FM 20-32

Obstacle Control Measures

Obstacle control measures are specific control measures that simplify
granting obstacle emplacement authority and providing obstacle control for all
levels of command (Table 2-1). Obstacle control measures are classified as—

• Zone.

• Belt.

• Group.

• Restriction.

Table 2-1 . Echelons of obstacle control and effect

Obstacle
Control
Measure

Echelon

Specific

Obstacle

Effects

Assigned

Size of Enemy AA/MC

Planning Guidance

Armored

Light vs
Armored

Zone

Corps or
division

Optional

Division/
brigade

Brigade/
battalion

Requires anticipating
belts and intents

Belt

Brigade

Optional but
normal

Brigade/
battalion

Battalion/
company

Requires anticipating
groups and intents

Group

Corps,
brigade,
division, or
battalion/TF

Mandatory

Battalion/TF

Company/
platoon

Based on individual
obstacle norms

Restriction

All

NA

NA

NA

Used only when
necessary to support
the scheme of
maneuver

Obstacle Zones

A protective obstacle is the only obstacle that can be employed outside a
designated obstacle zone, belt, or group.

A specific obstacle effect (disrupt, turn, fix, or block) may be assigned to
obstacle control measures. This enables the commander to direct the overall
effect of obstacles within a designated zone, belt, or group to support his plan.
At corps and division levels, assigning specific effects to obstacle zones is
optional. At brigade level, the commander will normally assign a specific effect
to the obstacle belts. At TF and battalion levels, obstacle effects for obstacle
groups are required. This ensures that subordinate commanders emplace
tactical obstacles that support the maneuver and fire plans. Assigning a
specific obstacle effect to a control measure becomes obstacle intent, giving the
obstacle effect, target, and location. Obstacle intent provides a direct link
between the obstacle plan, the scheme of maneuver, the commander's intent,
and the fire plan (direct and indirect). Obstacle intent is critical at brigade
level and below, and it becomes the foundation for obstacle group development
and design at theTF level.

Obstacle zones (Figure 2-9, page 2-16) are graphic control measures that corps
and division commanders use to grant obstacle emplacement authority to

Mine-Warfare Principles 2-15

FM 20-32

brigades (including armored cavalry regiments [ACRs] and other major
subordinate units). Corps and division commanders use zones to ensure that
subordinates emplace obstacles that support the higher commander's scheme
of maneuver, and to ensure that the obstacles do not interfere with future
operations.

PL TIGER
/ 52 ID

PL LION

PL JAGUAR

ENEMY

PL TIGER
Obstacle number prefix: 1052

52 ID

PL LION

PL JAGUAR

Unit

Zone

Priority

Remarks

1st Brigade

3d Brigade

No SCATMINEs with SD after H+2

3d Brigade

Block intent

Cavalry Squadron

Obstacle Belts

Figure 2-9. Obstacle zones

Obstacle belts (Figure 2-10) are graphic control measures that brigade
commanders use to constrain tactical-obstacle employment, and the belts
should not cross unit boundaries. Commanders plan obstacle belts within
assigned obstacle zones to grant obstacle emplacement authority to their
major subordinate units. This is normally the first level in which the
commander assigns an intent to the obstacle plan. It gives TF commanders
the necessary guidance on the overall effect of obstacles within a belt. It does
not designate that all obstacle groups within the belt must be the same effect.
It simply means that the sum effect of groups within the belt must achieve the
assigned belt effect. This serves to synchronize the obstacle effort within the
brigade, particularly between adjacent TFs. Obstacle belts also focus obstacles

2-16 Mine-Warfare Principles

FM 20-32

in support of the brigade scheme of maneuver and ensure that obstacles do not
interfere with the maneuver of any higher headquarters.

ENEMY

Unit

Belt

Intent Priority

Remarks

1-78

C1

Turn

1-78

C2

Block

1-79

B1

Fix

No long-duration SCATMINEs; must SD by H+2

1-79

B2

Turn

No long-duration SCATMINEs; must SD by H+2

1-4

B3

Fix

No long-duration SCATMINEs; must SD by H+2

Figure 2-10. Obstacle belts

Belts are planned to attack enemy regiments based on an analysis of enemy
battalion MCs. Brigades allocate maneuver companies based on the motorized
rifle battalion (M RB) AAs and organize TFs to defeat the motorized rifle
regiment (MRR). Obstacle belts and their intents are directed against MRR
AAs. This provides the appropriate level of guidance while preserving the TF's
need to refine the obstacle intent, based on how the TF will fight its allocated
companies.

Obstacle Groups

Obstacle groups (Figure 2-11, page 2-18) contain one or more individual
obstacles that are grouped together to provide a specific obstacle effect. TFs
use obstacle groups to ensure that company teams emplace individual
obstacles that support theTF scheme of maneuver. I n rare cases, brigades,
divisions, or even corps may use obstacle groups for specific tactical obstacles.

Mine-Warfare Principles 2-17

FM 20-32

Also, units perform detailed integration of obstacle groups with direct- and
indirect-fire plans.

Individual

Unit/BP

Group Intent Priority

Remarks

Company A/Screen

B3A

Disrupt

Team B/BP 30

B3B

Turn

Team D/BP 10

B3C

Fix

All groups restricted:

• Long-duration SCATMINEs are not allowed.

• Short-duration SCATMINEs must be
emplaced by H-3.

Figure 2-11. Obstacle groups

A TF allocates platoons against motorized rifle company (MRC) MCsand
task-organize them into companies/teams to defeat MRBs. Likewise, direct-
fire plans are designed based on the maneuver of MRBs and independent
M RCs. Therefore, obstacle groups are used to attack the maneuver of M RB-
size forces. Groups are designed specifically to support the direct-fire plan of
theTF. TheTF designates groups rather than obstacles because the location
of individual obstacles hinges on siting at the company/team level. The group
effect or obstacle intent drives obstacle siting and is therefore more important
to convey to commanders. There can be more than one type of obstacle group
to support the overall intent of an obstacle belt. This is because the belt design
is based on the brigade's scheme of maneuver, without knowing theTF's
direct-fire plan and scheme of maneuver. Groups are developed once the fire
plan is established.

Obstacle Restrictions

Commanders at all levels may use obstacle restrictions to provide additional
obstacle control. They may use obstacle restrictions to limit the specific types
of obstacles used (for example, no buried mines and no SCATMINEs that do
not self-destruct within 48 hours). These restrictions ensurethat subordinates
do not use obstacles with characteristics that impair future operations. It also
allows commanders to focus the use of limited resources for the main effort by
restricting their use elsewhere. Commanders may also use restrictions to

2-18 Mine-Warfare Principles

FM 20-32

prevent subordinates from emplacing obstacles in a certain area. This type of
restriction may be shown graphically as an obstacle-restricted area.

Fratricide Prevention

The modern tendency toward maneuver warfare and the disappearance of the
linear battlefield places repositioning forces at an increased risk of fratricide
by minefields. Obstacle control and the use of graphic obstacle control
measures are vital in preventing minefield fratricide at every echelon.

Obstacle control is further facilitated by positive C 2 of all sustainment traffic,
tactical repositioning, obstacle turnover, well-established and disseminated
traffic plans with traffic control, and strict adherence to minefield marking
procedures (discussed later in this chapter).

Maneuver-Plan Support

Commanders include obstacle planning in each level of the decision-making
process. This ensures that obstacle integration is effective and that the
obstacle plan is flexible enough to allow changes during the planning,
preparation, and execution phases of an operation. The following method is
used to integrate obstacle planning at the TF level; it uses the decision-
making doctrine contained in FM 101-5. Obstacle planning for brigade and
higher levels can be found in FM 90-7.

The focus of obstacle planning is to integrate obstacles into the maneuver
direct- and indirect-fire plans. This planning is directive and detailed in
nature and focuses on the determination of obstacle groups and the type and
amount of prepared positions. Actual obstacle siting, emplacement, and
position location are the purview of the company/team commander and are
normally supported by an engineer platoon.

TF-level defensive planning is part of the military decision-making process.
The engineer battlefield assessment (EBA) process provides the basis for
integrating engineer issues into the decision-making process.

Mission Analysis

The key activities during mission analysis areto—

• Determine facts and assumptions.

• Anal yze rel at i ve com bat power.

• Analyze the engineer battalion's/brigade's mission and the
commander's intent.

• Issue the commander's guidance.

Determine Facts and Assumptions

Defensive planning normally starts with the receipt of a warning order (WO)
from the higher headquarters to defend. The company executive officer (XO)
and the battlefield information control center (BICC) (or theTF engineer and
the I ntelligence Officer [US Army] [S2]) begin by developing a situation
template (SITEM P) that includes a modified combined obstacle overlay
(MCOO). The MCOO is a product developed during the intelligence
preparation of the battlefield (IPB) process. The MCOO development is a joint
effort of the engineer and the intelligence section of the TF 's tactical
operations center (TOC).

The MCOO should define the AAs and the MCs within theTF's AO. This
information is vital to obstacle planning. Obstacles are placed on AAs to
attack enemy maneuver. The AA analysis details potential EAs and indicates
where forces can defend with limited survivability construction, because a
reverse slope or undulating terrain provides natural concealment and cover.

Mine-Warfare Principles 2-19

FM 20-32

The threat evaluation and the enemy course-of-action (COA) development
detail how the enemy will potentially attack. They also provide an insight as
to what and where the enemy's objective and routes might be. The SI TEMP
helps the engineer to understand how the enemy will traverse through the
TF's sector and allows the engineer to gain an understanding of how and
where he can best attack the enemy's maneuver.

The SITE MP also depicts how the enemy's reconnaissance forces will enter
the sector. This is especially important when countering the enemy's ability to
reconnoiter obstacle efforts.

The engineer must articulate the current capabilities of the engineer forces,
its current combat power, and its ability to support the TF. Assumptions of
future capability or potential reinforcement by other engineers should be
analyzed. Specific characteristics of special engineer equipment and
SCATMINE systems are detailed for the staff. An initial Class IVA/ supply-
point location and an operation plan should be developed with theTF staff
(note that the TF has responsibility for Class IVA/ supply-point operation).
The XO/first sergeant (1SG) works with theTF and the engineer battalion
Supply Officer (US Army) (S4) to ensure that delivery of Class IVA/ barrier
material supports theTF counter mobility plan.

Analyze Relative Combat Power

The engineer compares friendly and enemy combat power and identifies
possible obstacle requirements that offset potential enemy breaching and
direct- and indirect-fire capabilities. The actual inclusion of the obstacles
normally occurs after COA development. During this phase, the engineer
finishes his EBA to gain an understanding for the engineer company's ability
to support theTF.

Analyze the Engineer Battalion's/Brigade's Mission and the Commander's Intent

The staff analyzes and identifies information from the maneuver brigade
order and the commander's intent that will potentially impact defensive
planning. The engineer analyzes the maneuver brigade/engineer battalion
commander's intent to determine potential obstacle placement, obstacle
intent, and construction priority based on his concept of the operation.

The TF must identify tasks and limitations imposed from the brigade
operation order (OPORD). These might include obstacle belts with or without
specific intents, obstacle-restricted areas, or restrictions on the type of
obstacles. Also, the brigade OPORD might specify reserve, situational, or
directed obstacle groups.

The engineer must identify the TF's total obstacle capabilities. Available
assets include engineer units, SCATMINE systems, and other units that can
provide additional manpower for obstacle construction. Engineer-equipment
status, work rates, and the time available must be evaluated in detail.

NOTE : Work rates should only be used in the absence of unit-
developed planning factors.

Table 2-2 provides planning factors for the mine dump. Tables 2-3 through 2-6,
pages 2-21 through 2-23, provide planning factors for obstacles. Special focus
to limited visibility work rates and engineer squad strengths must be made
when making total -capability estimates. Plan to accomplish obstacle siting

2-20 Mine-Warfare Principles

FM 20-32

and Class IV/V supply-point setup during daylight hours, and plan toemplace
mines during limited visibility hours as much as possible.

Table 2-2. Planning factors for the mine dump

Number of Personnel

Quantity of Mines

Required Equipment

2-man team (2 minutes per mine)

25 mines per hour

Shears, metal cutting

Grease, automotive and artillery

Rags

Work gloves

Flashlight

Night-vision goggles

Pliers

Squad (7 soldiers and an NCO)

100 mines per hour

Platoon (with leadership)

300 mines per hour; 3,600 mines
per day

Company

10,800 mines per day

NOTE: Soldiers work 50 minutes per hour, 12 hours per day.

Table 2-3

Planning factors for work rates

Survivability

Time Required to Construct

With D7F Dozer

With ACE

With SEE

Hull-defilade position

1 BTH

1.5 BTH

NA

Turret-defilade position

2.5 BTH

3.5 BTH

NA

HMMWV TOW position

1.5 BTH

2 BTH

NA

Vehicle-protective position

0.75 BTH

1 BTH

NA

Dismount-crew position

NA

NA

1 SEEH

Individual-fighting position

NA

NA

0.5 SEEH

Countermobility

With D7F Dozer

With ACE

In Man-Hours

Antitank ditch

1 BTH/70 m

1 BTH/50 m

NA

Standardized disrupt minefield

NA

NA

1.5 PH

Standardized fix minefield

NA

NA

1.5 PH

Standardized turn minefield

NA

NA

3.5 PH

Standardized block minefield

NA

NA

5PH

Triple-standard concertina

NA

NA

1 PH/300 m

Road crater

NA

NA

1.5 SH

Point minefield

NA

NA

1 SH

Concertina roadblock

NA

NA

1 SH

Bridge demolition (massive)

NA

NA

2SH

Bridge demolition (steel)

NA

NA

1 SH

Mine preparation at the TF Class IV/V
supply point

NA

NA

1 SH/1 00 mines

LEGEND:

BTH (blade team hour). One blade team working for one hour. A blade team consists of two engineer

blades (two dozers, two ACEs, or one ACE and one dozer). One vehicle digs (cutter) while the other

spreads the spoil (striker). A dozer-ACE blade team uses the dozer BTH.

SEEH (SEE hour). One SEE working for one hour.

PH (platoon hour). One platoon (3 squads) working for one hour.

SH (squad hour). One squad working for one hour.

Mine-Warfare Principles 2-21

C2, FM 20-32

Table 2-4. Planning factors for standardized row minefields

Effect

Resource
Factor

Front

Depth

Full-Width
AT Mines

Track-Width
AT Mines

Frag AP Mines

Disrupt

0.5

250 m

100 m

42

84

NA

Fix

1.0

250 m

120 m

63

84

NA

Turn

1.2

500 m

300 m

336

168

NA

Block

2.4

500 m

320 m

378

168

84 (Korea Only)

Table 2-5. Planning factors for scatterable minefields

System

Minefield Size

SD Time

Arming Time

ADAM

400 x 400 m
200 x 800 m

4hr
48 hr

Within 1 min
after ground
impact

RAAM

400 x 400 m
200 x 800 m

4hr
48 hr

2 min 45 sec

Volcano (one load = 1 60
canisters or 960 mines
[800 AT and 1 60 AP])

Turn or block (1 per load):

• Ground: 555 x 320 m

• Air: 557 x 320 m

Fix or disrupt (4 per load):

• Ground: 277 x 120 m

• Air: 278x1 20 m

4hr
5 days
1 5 days

2 min

MOPMS

70 x 35 m

4hr*

89 sec

*Can be recycled 3 times for a total of 1 3 hr

2-22 Mine-Warfare Principles

FM 20-32

Table 2-6. Ranges of common weapons

Weapon

Maximum
Effective Range

Planning
Range*

FRIENDLY WEAPON SYSTEMS

M16A2

580 m

400 m

M249 SAW

1,000 m

800 m

M60

1,100 m

1,100m

M203

Area

350 m

350 m

Point

160 m

160 m

M2, .50 Cal

Area

1,830 m

1,830 m

Point

1,200 m

1,200 m

MK19

Area

2,200 m

2,200 m

Point

1,600 m

1,600 m

AT4

300 m

300 m

M47 Dragon

1,000 m

800 m

Javelin

2,000 m

2,000 m

M1 Abrams tank

105 mm

2,500 m

2,000 m

120 mm

3,000 m

2,500 m

M2 Bradley ITV

25 mm (APDS)

3,000 m

1,700 m

25 mm (HEI-T)

3,000 m

1,700 m

TOW2

3,750 m

3,750 m

60-mm mortar

HE

3,400 m

50 m (min)

WP

4,800 m

50 m (min)

ILLUM

931 m

50 m (min)

81 -mm mortar

HE

4,595 m

75 m (min)

WP

4,595 m

75 m (min)

ILLUM

3,150 m

75 m (min)

4.2-in mortar

HE

6,840 m

770 m (min)

WP

5,650 m

920 m (min)

ILLUM

5,490 m

400 m (min)

SOVIET-STYLE WEAPON SYSTEMS

BMP, 73 mm

800 m

800 m

AT3 missile

3,000 m

3,000 m

AT5 missile

4,000 m

4,000 m

BMP-2

2,000 m

2,000 m

BTR, 14.5 mm

2,000 m

1,000 m

T-72 tank, 125 mm

2,100 m

2,000 m

T-80 tank, 125 mm

2,400 m

2,000 m

T-80 AT8

4,000 m

4,000 m

The planning range is based on ideal weather conditions during daylight.

Mine-Warfare Principles 2-23

FM 20-32

Issue the Commander's Guidance

The commander should be as specific as possible with his initial obstacle
guidance. If the commander narrows the COA focus, he should also provide
obstacle guidance. H is guidance is a key factor to an early start and must be
solicited if not offered.

Course-of -Action Development

Detailed planning begins following the COA development (Figure 2-12). The
engineer focuses on four specifics of obstacle planning in the scheme of
engineer operations (SOEO) for the defensive plan:

• Direct -/indirect-fire analysis.

• Obstacle-intent integration.

• Obstacle priority.

• M obi I i ty requ i rements.

Figure 2-12. TF defense COA

Direct-/! ndirect-Fi re Analysis

The direct-/indirect-fire analysis examines how engineers can best use
obstacles (within the commander's intent) to enhance the direct-/indirect-fi re
plan. Figure 2-13 shows a sample direct-fire analysis. This analysis can be

2-24 Mine-Warfare Principles

FM 20-32

used to formulate obstacle locations with the direct-fire plan. The engineer
must have a fundamental understanding of the direct-/indirect-fire and
maneuver plans and theTF's organization of the EA to effectively integrate
obstacles with the direct-/indirect-fire plan.

Figure 2-13. TF direct-fire analysis

Synchronization of direct and indirect fires with obstacles multiplies the
relative effect on the enemy. An obstacle is an excellent location for
preplanned artillery and mortar fires. These fires can eliminate dismounted
breaching efforts. I ndirect fires contribute to the threat's ability to breach,
making the obstacle more effective and providing direct-fire systems a higher
probability to kill.

Obstacle-Intent Integration

The engineer determines locations for the directed obstacle groups. Groups
are placed on theCOA overlay to support the maneuver plan. This location is
for planning only and will normally be adjusted after the ground
reconnaissance.

Obstacle groups target specific enemy elements based on the SITE MP. The
engineer generally allocates an obstacle group against a battalion-size AA.
This approach mirrors the staff's placement of a company/team against the
same enemy force. The company's/team's fire responsibility drives the
placement of the obstacle groups. The engineer advises the commander on

Mine-Warfare Principles 2-25

FM 20-32

which specific effect each directed obstacle group must achieve. He plans
obstacle groups to—

• Disrupt the enemy.

• Turn the enemy into an area where friendly units can mass fires.

• Fix the enemy in the EA and enhance his direct-fire destruction.

• Block the enemy from using an AA.

The engineer integrates directed obstacle groups with theCOA. The obstacle
effects areshown on theCOA overlay using obstacle-effect graphics (Figure2-14).
The engineer draws the obstacle-group graphic to reflect the location, the
target, and the specific intent of the group as accurately as possible. The
engineer should visualize how the terrain naturally effects maneuver. Terrain
visualization is vital to proper obstacle-group design.

Figure 2-14. TF obstacle-intent integration and priorities

Note the placement and the effect of obstacle groups in Figure 2-14. First, the
engineer must manipulate the MRB into the EA. The turn groups (2 and 5),
combined with a heavy volume of AT fires from a company team at the turning
point, achieves this. In the EA, particularly where theTF fires are massed, a
fix group (3) slows the enemy and increases the effects of the fires. A block
group (1) in the south, along with direct fires from a company team, will stop
the advance of any element along the southern AA. A disrupt group (4), with

indirect fires, will break up the C 2 and the tempo of the attacking force.

2-26 Mine-Warfare Principles

FM 20-32

Protective obstacles in front of all team positions protect the teams from the
enemy's final assault.

Obstacle Priority

The staff determines the priority of each group depicted on the overlay.
Priority is established by the commander's intent and the most likely enemy
COA. The obstacle priority should reflect the TF 's greatest obstacle
requirement. The primary obstacle effort can be with an economy of force
where the commander needs more obstacles to overcome a shortage of direct-
fire systems. TheTF engineer should be cognizant of flank protection, weapon
types and ranges, and the overall commander's intent for the entire force
before placing obstacle priority on the main EA. Priorities assist the engineer
in allocating resources and ensuring that the most critical obstacle groups are
emplaced first.

I n Figure 2-14, the first priority is to turn the enemy where the fires are
massed. The second priority is to deny the enemy access (block effect) to the
southern AA. The fix effect is the third priority because it enhances theTF
fires in the EA but only slows the enemy). The block effect is a higher priority
than the fix effect because it stops the enemy from flanking the TF. The
disrupt effect is the last priority.

Mobility R equirements

The engineer identifies theTF 's mobility requirements. Obstacle groups
should not be arrayed along potential counterattack routes or where there is a
potential to hamper unit repositioning. Mobility assets should be used to
counter potential enemy situational obstacles and friendly obstacles that
might hinder friendly maneuver. TheTF engineer must consider the
commander's mobility requirements and plan for mobility assets so he can be
ready when and where he is needed.

Course-of -Action Analysis

The staff war-games the COAs to determine their viability and recommends
the best COA to the commander. The engineer refines the SOEO during this
process as well. Obstacles should be considered within the context of the
maneuver COA (F igure 2-15, page 2-28).

The engineer staff officer should consider thefollowing:

• Enemy reactions at the obstacle groups (breaching or bypassing
capability) versus the desired obstacle effect.

• Enemy breaching capabilities that make one obstacle type preferable
to another (such as an AT ditch versus a minefield).

• Obstacle locations that hinder friendly maneuver.

• The compatibility of obstacle effects and weapon-system capabilities.

• Adequate direct-/indirect-fire control measures and targeting that
support the obstacle effect. The effects of artillery and obstacles must
be synchronized to gain the desired effect on the enemy's maneuver.

• Locations and types of enemy situational obstacles that make one type
of breaching asset preferable to another.

Mine-Warfare Principles 2-27

FM 20-32

Figure 2-15. Obstacle-plan refinement

After war gaming, the staff adjusts the COA (including the obstacle pi an) by-
Changing the location of obstacle groups.
Changing the obstacle effects.
Adding more situational obstacles.
Adding more reserve obstacles.
Identifying other mobility requirements.
Refining artillery targets based on obstacle-group changes.

Mobility R equirements

The staff determines which obstacles require lanes and determines the closure
criteria for the lanes. It also determines obstacle-restricted areas that support
theTF's maneuver. Lanes and bypasses are determined using tactical
repositioning requirements developed during the COA analysis. Requirements
for rehearsal movement, placement of the target reference poi nt (TRP), and
logistical support of forward TF elements are also considered in lane
development. Mobility requirements identified during COA development are
synchronized and refined during COA analysis. Additional mobility
requirements identified during war gaming are resourced and planned. (Lane
marking is discussed later in this chapter.)

2-28 Mine-Warfare Principles

FM 20-32

Obstacle Design/R esourcing

After theCOA analysis, the engineer conducts a detailed study of the obstacle
plan to determine resource requirements. Groups are resourced using the
methods previously discussed. The TF engineer resources the obstacle groups
based on their assigned priorities. Once the engineer has developed the
resource requirements for the obstacle groups, he plans the individual
obstacles within the group.

If time permits, a detailed ground reconnaissance of the obstacle-group
location can be conducted. This will allow a more detailed analysis of the
obstacle requirement for that AA, and then the engineer can plan individual
obstacles. The TF engineer usually designates the intent to guide the
companies/teams; the company/team commanders and their supporting
engineers complete the actual design of the obstacle groups.

Decision and Execution

The engineer makes adjustments to the SOEO based on the COA that the
commander approves. The engineer then provides oral, written, and/or
graphical orders with sufficient detail to allow the subordinate units to
conduct the operation. The engineer provides critical information using the
scheme-of-obstacle overlay and the obstacle-execution matrix.

Scheme-cf -Obstacle Overlay

The scheme-of-obstacle overlay (F igure 2-16, page 2-30) depicts the location of
the TF's obstacle groups, brigade-directed obstacle groups (if any), and
obstacle belts within the TF's sector. The overlay also includes any obstacle
restrictions dictated from a higher headquarters. The overlay depicts the
obstacle groups using the standardized obstacle-effect symbols. The overlay
does not generally show individual obstacles unless the engineer has had
sufficient time to conduct a thorough ground reconnaissance where exact
obstacle locations have been identified. The engineer must exercise extreme
caution if he uses individual obstacles on the overlay. He must ensure that
inexperienced leaders do not attempt to empl ace obstacles exactly as shown on
the overlay, but instead, properly site the obstacle with the company/team
commander. The scheme-of-obstacle overlay graphically depicts how the
commander seeks to influence enemy maneuver through obstacles.

Obstacle-Execution Matrix

The obstacle-execution matrix includes specific instructions and detailed
information concerning the obstacle groups shown on the scheme-of-obstacle
overlay. Develop an obstacle-execution matrix for all situational, reserve, and
direct obstacles within theTF area. As a minimum, the matrix should include
the information shown in Figure 2-17, page 2-31.

Mine-Warfare Principles 2-29

FM 20-32

Co D sites

A1D.

No bypass allowed

at wood line.

Tm C sites A1C
and removes
bypass markings
for Lane Blue.

/

BLUE

Lane Red closed
after scouts have
passed. Tm B
closes the lane
with MOPMS.

Tm B sites A1A. No
bypasses allowed
after lane closure.

Figure 2-16. Scheme-of-obstacle overlay

2-30 Mine-Warfare Principles

FM 20-32

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Mine-Warfare Principles 2-31

FM 20-32

SITING AND EMPLACING TACTICAL MINEFIELDS

This section outlines the principles for siting tactical minefields to support the
company/team. These principles apply to all methods of emplacement-
standard pattern, row mining, and SCATMINE systems. The focal point of the
discussion on siting is the coordination that must occur between the
emplacing engineer (normally the engineer platoon leader) and the maneuver
company commander. Coordination between the engineer platoon and the
maneuver company is perhaps the most vital component of effective obstacle
integration, and it is also a vital component in EA development. Obstacles are
directly integrated with weapon effects, capability, and the fire plan at this
level. The two subcomponents of tactical-obstacle siting are coordinating with
the maneuver commander and siting the minefield.

Coordinating with the Maneuver Commander

Effective coordination with the maneuver company/team commander who will
fight the obstacle(s) is essential to realizing the full potential of minefields as
a combat multiplier. I n short, the emplacing engineer becomes the maneuver
company/team commander's team engineer for the mission. The engineer, the
fire-support team (FIST), and the maneuver commander must work closely to
ensure complete integration of the minefield into all aspects of the company
plan. The engineer must be integrated into the maneuver company/team EA
development process. Throughout each step of the process, the engineer must
provide the maneuver commander and the FIST with the engineer expertise
necessary to ensure complete and effective obstacle integration.

Before the emplacing engineer can conduct effective coordination, he must
have tools and information from theTF order that serves as common ground
between the emplacing engineer, the FIST, and the maneuver commander.
The order drives the integration of tactical obstacles into the fire plan and
ensures that the obstacles affect their intended enemy target in a way that
supports the scheme of maneuver.

Modified Combined Obstacle Overlay

The MCOO is a product from the I PB process that graphically depicts the
maneuverability of the terrain. It depicts slow-go and no-go terrain relative to
the type of enemy force. It also defines AAs and MCs that the enemy may use
for its attack. Since tactical obstacles attack the enemy's maneuver and must
complement the existing terrain, the MCOO is vital to obstacle siting. It helps
ensure that obstacles correctly address the enemy AAs and MCs. It also helps
select how and what part of the enemy formation will be directly attacked by
obstacles, and it shows the effect the obstacles will have on the enemy's
maneuver.

Situation Template

The SITE MP is developed by the maneuver battalion S2 and theTF engineer
during the I PB. It estimates how the enemy will attack, in terms of size and
type of units, and theformations it will use. Tactical obstacles are employed to
produce specific effects on specific enemy targets. Therefore, the SITE M P
helps the engineer and the maneuver commander site and emplace obstacles
in a way that attacks the intended target. The SITEM P may also depict the

2-32 Mine-Warfare Principles

FM 20-32

likely routes for enemy reconnaissance elements. This helps the engineer and
the maneuver commander analyze requirements for reconnaissance and
surveillance (R&S) patrols that defeat enemy attempts to reconnoiter the
obstacles and reduce enemy effectiveness before the attack. The type of
formations the S2 expects the enemy to use during the entire course of the
attack is also vital information. The SITE MP should identify when the enemy
is in march, prebattle, and attack formations. The enemy formation may
impact on the necessary front of obstacle groups and the obstacle groups'
effectiveness in achieving the intended effect on enemy maneuver.

Commander's Intent

The emplacing engineer, the FIST, and the maneuver commander must have a
common understanding of the battalion commander's intent. The battalion
commander's intent is his vision of the battle and normally outlines what
actions the unit must do to accomplish the mission. The commander's intent
may include key aspects of the plan that he wants to emphasize to
subordinates to synchronize the actions of subordinates toward a single
purpose. The engineer must understand the commander's intent and how it
relates to integrating obstacles. The engineer should always ensure that the
obstacles he is emplacing support the commander's overall intent.

Maneuver Graphics and the Fire Plan

I n order to fully support the scheme of maneuver, the engineer must have and
understand the maneuver graphics on the battalion's operational overlay. The
maneuver graphics use symbols to depict the missions of each subunit within
the battalion. Maneuver control measures such as battle positions, sectors,
phase lines, passage lanes/points, and counterattack axis are vitally
important to understanding the plan and integrating tactical obstacles. The
maneuver graphics may include direct-fire control measures that direct how
and where combat forces will mass, shift, and lift fires to destroy the enemy.
Direct-fire control measures include EAs, trigger lines, and TRP and unit
boundaries. I n short, they dictate the direct-fire responsibilities of each
subordinate. Understanding the direct-fire plan and the organization of the
engagement is fundamental to integrating obstacles with fires. The maneuver
graphics also give the engineer an appreciation of how tactical obstacles
supporting one unit must complement the adjacent units. This is particularly
true of adjacent EAs or plans requiring any tactical repositioning of forces.

Obstacle-Execution Matrix

The obstacle-execution matrix includes specific instructions and detailed
information concerning the obstacle groups shown on the scheme-of-obstacle
overlay. This matrix gives the engineer critical information on minefield
groups that will beemplaced within the company's/team's AO. As a minimum,
the obstacle-execution matrixshould include the information shown in Figure
2-17, page 2-31.

Scheme-of -Obstacle Overlay

At the maneuver battalion level, the scheme-of-obstacle overlay depicts the
location of brigade-directed belts, TF obstacle groups, and any directed
obstacles within the battalion sector. Any obstacle restrictions attached to an
obstacle control measure (belt or group) that preclude the employment of

Mine-Warfare Principles 2-33

FM 20-32

certain types of obstacles are annotated on the overlay. A scheme-of-obstacle
overlay is a graphic control measure that defines the general location of the
obstacle groups and the effect to be achieved by them. The scheme-of-obstacle
overlay does not normally depict individual obstacle locations. The location of
individual obstacles within a group is determined during the siting process
between the emplacing engineer and the maneuver company commander.
When overlaid on the maneuver graphics and the SITE MP, the scheme-of-
obstacle overlay should depict the essential elements of obstacle integration:

• E nemy targeted by the obstacle.

• Location of the obstacle on the battlefield.

• Unit covering the obstacle.

• Directed link between the obstacle effects and the fire plan.

Fire-Support Plan

The emplacing engineer should be familiar with the key elements of the fire-
support plan. He must understand the general scheme of fires and how the
fires support the scheme of maneuver, the commander's intent, and the
obstacle plan. Normally, the emplacing engineer does not need the entire fire-
support overlay depicting the location of all targets. However, he should know
the location of fire-support targets directed by the battalion to cover obstacles.
The emplacing engineer should know who has the priority of fires for each
phase of the battle. The emplacing engineer should also know the location and
the type of priority targets or FPF allocated to the maneuver company he is
supporting. During coordination with the maneuver company, the emplacing
engineer should discuss the fire-support plan with the company FIST and get
updates on changes to the plan as well as any company-level fire-support
plans that may impact on the integration of obstacles.

Combat Service Support

The engineer must be familiar with the plan for combat service support (CSS).
In particular, the engineer must know the location of major supply routes into
and through the battalion area, the location of the battalion logistics release
point (LRP), what routes the maneuver company will take from its position to
the LRP, and the location of key battalion logistics nodes. The emplacing
engineer must always be cognizant of the sustainment traffic flow and the
impact obstacle emplacement has on sustainment operations. Of particular
concern to the engineer is the location of the Class I V/V supply point and the
routes to it.

Battlefield Operating System

During coordination with the maneuver company commander, a checklist or a
framework is a useful tool for organizing thoughts and formulating questions.
Below is a list of considerations or points of coordination that should drive the
integration of the emplacing engineer and the maneuver company
commander. The list is organized using the Battlefield Operating System
(BOS) because it provides a logical sequence and a framework that is easily
remembered.

• Intelligence.

2-34 Mine-Warfare Principles

FM 20-32

— Enemy AAs and MCs (mounted and dismounted).

— Likely enemy COA and possiblereactionstotheobstacles.

— Enemy breach capability.

— Enemy reconnaissance routes and friendly counterreconnaissance
or R&S plans, particularly company-level patrols.

— Likely enemy formations and transitions between formations.
Maneuver.

— Specified, implied, and essential tasks of the maneuver company.

— Higher commander's intent.

— Organization of the defensive position, including—

> Task organization (type of weapons).

> Decisive poi nt or defeat mechanism.

> Organization of direct fires in the EA.

> Location and marking of direct-fire control measures.

> Position of weapons to cover assigned direct-fire
responsibilities.

— Tactical mobility requirements of the maneuver company and any
adjacent units, including—

> Counterattack axis.

> Repositioning of forces and their routes to alternate,
supplementary, or subsequent battle positions.

> E mployment of reserves.

> Passage of lines.

— Obstacle protection measures.
M obi I ity/su rvi vabi I ity.

— Intent of tactical obstacles covered by the maneuver company
(enemy target, obstacle location, and obstacle effect).

— Obstacle control measures and restrictions imposed by higher
headquarters.

— Mobility requirements (lanes/gaps), as identified above in
maneuver.

— Mutual support between the obstacle location, the fire plan,
obstacle effects, and survivability positions.

— Security for engineers provided by the maneuver unit supported.
Fire support.

— Location of the company Fl ST and frequency of fire support.

— Updates on the tentative fire-support plan.

Mine-Warfare Principles 2-35

FM 20-32

— Allocation of fires to thecompany, including—

> Artillery or mortar targets.

> Priority targets, types of targets, and theFPF.

— Covering obstacles and their effects with indirect fires.

— Indirect -fire control measures to synchronize direct fires, indirect
fires, and obstacles.

— Area-denial artillery munition (ADAM)/remote antiarmor mine
(RAAM) use (lane closure and breached obstacle repair).

— Registering fires. (Deconflict with obstacle emplacement;
registration should occur after obstacles are sited but before
emplacement.)

— Company fire-support execution matrix.

— Means for obtaining fire support, if enemy contact is made during
emplacement.

Air defense.

— Enemy air AAs during emplacement.

— Update on changes to air-defense warning and weapons status.

— Location of air-defense systems that can cover engineers
emplacing obstacles.

— Method of obtaining early air-defense warning.
CSS.

— Tentative location of the mine dump, if used, within the company
position and routes from the mine dump to obstacles.

— Routes the company plans on using to conduct logistics package
(LOGPAC) operations that must remain open.

— Manpower assistance for operations at the Class I VTV supply point
and theminedump.

— Casualty evacuation routes for scouts, observation posts (OPs),
and ADA systems.

C 2 .

— Location of the commander during defensive preparation.

— Frequency-modulated (FM) net of the supported company and the
means of communication.

— Unit boundaries affecting obstacle emplacement.

— Timeand placeof the company/team order.

— Coordination that must occur with adjacent units.

— Obstacle reporting and recording requirements.

2-36 Mine-Warfare Principles

FM 20-32

— Control and execution of situational and reserve obstacles.

— Lane-closure responsibilities and procedures.

— Time and method of obstacle turnover, including lanes.

— Company/team understanding of theobstacle intent.

Siting the Minefield

The emplacing engineer and the company/team commander site individual
obstacles to achieve synchronization between the obstacle effect and fires.
Siting is a key component to the EA development process, and it represents
the final adjustments to the obstacle location and the fire control measures
before empl acement.

Certain preconditions are necessary to site individual obstacles. First, the
company/team commander decides where he plans to mass fires and marks
the necessary fire control measures on the ground. The location of these
control measures must be clear, since they are the basis for obstacle siting.
The commander then identifies tentative locations for key weapons within the
position or the sector. Finally, the commander and the engineer must both
understand the intent of the obstacle group.

Obstacle siting concentrates on marking the obstacle group as a whole instead
of marking each individual obstacle. In broken terrain, however, it may be
easier to site individual obstacles. The company/team commander and the
emplacing engineer use vehicles or soldiers from the company/team, the
engineer platoon, or both to simulate the enemy force and do the physical
marking. The simulated enemy force moves into the EA to the enemy side of
the obstacle group. The engineer platoon leader and the company/team
commander collocate near the weapons covering the obstacle. As a technique,
one or all of the tanks, Bradleys, and other crew-served weapons may occupy
their position and contribute to the siting process. All participants in the
siting process use a common FM net to communicate during siting.

The simulated enemy force moves intotheEA, simulating the enemy's attack.
It deploys into a formation of front that is similar to the expected enemy
formation. Once it is near the marked fire control measures, it places markers
at intervals as it drives the trace of the obstacle-group effect (or individual
obstacles in broken terrain). It remains oriented on key fire control measures
to ensure that obstacle location and effect are synchronized with fires. During
the process, each participant verifies that he can cover the obstacle, notes the
location of fire control measures and obstacles, and records the appropriate
data on range cards. As the simulated force drives the obstacle trace, siting
participants also identify dead space and requirements to refine the location of
the obstacle group and fire control measures. Figure2-18, page2-38, illustrates
how the engineer and the company/team commander work together to site
turn- and fix-obstacle groups.

Mine-Warfare Principles 2-37

FM 20-32

TURN-OBSTACLE
GROUP

FIX-OBSTACLE
GROUP

<3

+ Planned TRP
R Marked TRP

CZ> Bradley position
TT Tank position
■mj. Engineer vehicle

f" Group marker
- - Individual minefield

Figure 2-18. Minefield siting

2-38 Mine-Warfare Principles

FM 20-32

Once the company/team marks the general limits and the orientation of the
obstacle group, the engineers can begin marking individual obstacles (if not
already done). To mark individual obstacles, the engineer platoon uses the
group markers as guides. As shown in Figure 2-18, the group markers may
lend themselves well as the start and end points of individual obstacles;
however, this is not always the case. As theengineer platoon refines thegroup
limits into the site of individual obstacles, the platoon can then begin the
necessary site layout based on the method of obstacle emplacement.

Siting is not the last thing done during preparations. The time and resources
involved in emplacing tactical obstacles require that siting begins
concurrently with establishing the defensive position. It is imperative that the
unit sites the obstacles as soon as the company/team commander has
established the EA and identified tentative positions for key weapons. It is not
necessary that all weapons are in place and dug in before siting. Normally,
well-marked fire control measures and one known position per maneuver
platoon (not dug in) areall that is required to site the obstacles effectively.

Emplacing Minefields

Based on thegroup effect, resources allocated, and theengineer plan, the
platoon leader determines the method of emplacement for individual
minefields. The procedures for emplacing scatterable, row, and standard-
pattern minefields are contained in Chapters 3, 6, and 7, respectively.

Determining Resource Requirements

Theengineer must determine the number of individual minefields needed to
make up the group and ensure the allocation of required resources. The
amount of linear obstacle effort for a group is equal to the width of theAA,
multiplied by the resource factor. In Figure 2-19, page 2-40, theAA is 1,500
meters wide, the tactical-obstacle effect is to turn the enemy, and the resource
factor is 1.2. The linear minefield requirement is 1,800 meters. One turn-effect
minefield has a front of 500 meters (1,800/500 =4 minefields [round up]). The
number of mines and thetime required toemplaceeach minefield depends on
the emplacement method.

MINEFIELD SUPPLY OPERATIONS

Requests for Class I VA/ obstacle material that are originated at TF level or
below go to the TF S4. TheTF S4 processes the requests and sends them to
the forward support battalion (FSB). The FSB processes the requests and
forwards them to the brigade-level F SB, the division material-management
center (DMMC), and the corps material-management center (CMMC).

The issue of Class IV obstacle material normally involves large quantities of
material; therefore, corps support elements normally use their transportation
assets to deliver the material directly to the emplacement sites or to the Class
IvTV supply point.

Units request Class V obstacle material somewhat differently. TheTF S4
notifies the brigade S4 of Class V requirements. The brigade S4 notifies the
division ammunition officer (DAO) in the DMMC, who authorizes Class V
issue by the ammunition transfer point (ATP). Class V obstacle material,

Mine-Warfare Principles 2-39

FM 20-32

Width of AA/MC = 1 ,500 m
Obstacle effect: Turn
Linear effort resource factor: 1 .2
Turn minefield front norm: 500 m

Determine number of minefields in the group

1 ,500 x 1 .2 = 1 ,800 m linear effort

1 ,800/500 = 4 turn minefields (round up)

Figure 2-19. Example of minefield resourcing

unlike most ammunition, is delivered to the user at the obstacle emplacement
site or the Class IvTV supply point.

A supply request includes the quantity, the required delivery time, the
transportation responsibilities, and the desired delivery location. The quantity
includes the total for each type of obstacle. There may be several Department
of Defense identification codes (DODICs) and national stock numbers (NSNs)
involved, depending on the types of obstacles required. The required delivery
time is very important for ensuring an early start on the preparation of the
battlefield because the lack of material could adversely affect the mission.
Transportation responsibilities must be clearly understood. Material handling
equipment (MHE) is required to ensure a rapid turnaround of haul assets.

I n addition, the brigade staff coordinates with theTF staff to identify the
location of Class IvTV supply points in theTF sectors. Prompt identification of
TF Class IvTV supply points is required if the obstacle material is forwarded
from the corps into theTF sector. If the material is not forwarded into theTF
sector, the brigade is responsible for delivering it to theTF.

At theTF level, sustaining obstacle operations is an extremely difficult task.
Centralized throughput operations by the corps or the division stop at theTF
level. Mass quantities of obstacle material, especially mines, are centrally
received, broken down into minefield packages, and then distributed
throughout the sector based on the obstacle plan. At some point in the
distribution plan, the TF turns over control of the obstacle material to
engineers who then emplace the obstacles. Obstacle logistics (especially for
mine warfare) at theTF level can be complex, require prudent use of scarce

haul assets and MHE, and demand positive C 2 .

2-40 Mine-Warfare Principles

FM 20-32

The supply of obstacle material may vary slightly for obstacle groups
developed at corps, division, and brigade levels. The staff at the level where
the obstacle group is planned determines the resources required for the
obstacle. It also determines how theemplacing unit will get the material. For
example, if the corps staff plans a reserve obstacle group but the detailed
planning is done at TF level, theTF resources the obstacle group. However, if
the corps staff plans the obstacle group in detail, it determines the resources
required. The corps staff also plans the delivery of obstacle material to the
emplacing unit. Alternately, the corps staff could direct theemplacing unit to
pick up the obstacle material from a location such as the corps storage area.

This section describes some of the underlying principles in mine supply
operations. It concentrates on the flow of Class I V/V material (mines) through
the battalion sector. The maneuver unit is responsible for the flow of obstacle
material within the maneuver battalion sector; however, it is effectively a
shared responsibility between the engineer and the maneuver unit.

Resupply Nodes

There are two critical mine resupply nodes within theTF sector— the Class
I V/V supply point and the minedump. The relative locations of theClass I V/V
supply point and the minedump are shown in Figure 2-20.

B3A

DUMP VJ

MINE
DUMP

Figure 2-20. Mine resupply

Class I V/V Supply Point

A Class W//V supply point is a central receiving point for obstacle material in a
TF sector. It is where theTF receives and transfers control of obstacle
material pushed forward by higher levels. The supply point is established and
operated by theTF and is centrally located to support all planned obstacles
within theTF sector. Where the tactical-obstacle plan allows, the supply point

should be located near theTF combat trains to better facilitate C 2 and the
availability of equipment. TheTF combat trains command post (CTCP) should

Mine-Warfare Principles 2-41

FM 20-32

provide C 2 of operations at the Class IV/V supply point. TheTF engineer will
normally furnish a representative that provides technical assistance to the
CTCP.

The main purpose of a Class IV/V supply point operation is to receive obstacle
material and reconfigure it based on the requirements for each obstacle group.
Each supply point must have a dedicated S4 representative to track the flow
of obstacle material in and out of the supply point. The supply point should
have dedicated MHE to off-load the bulk quantities of obstacle material and
reconfigure them into minefield packages as required. Obstacle material is
normally broken down into minefield packages if the material is not already
delivered in combat-configured loads. This may require a dedicated engineer
representative to ensure that obstacle material is configured properly. Table 2-
7 shows personnel requirements for a Class IV/V supply point.

Table 2-7. Personnel requirements for a Class IV/V supply point

Personnel

Responsibilities

TF S4/S4 NCOIC

Provides overall C 2 and Class IV/V accountability
Coordinates for MHE
Is assisted by the RTO

TF engineer representative

Supervises organization of Class IV/V material into
packages to support obstacle groups

Provides technical assistance on Class IV/V supply-
point setup and mine uncrating and inspection

Infantry squad*

Downloads incoming Class V trucks

Infantry squad*

Downloads incoming Class IV trucks

Infantry squad*

Uploads outgoing Class IV/V trucks

Two infantry squads*

Uncrates and inspects mines

Support PL/PSG

Provides C 2 for cross loading of Class IV/V material

Infantry squad*

Provides local security for the Class IV/V supply point

* or equivalent-sized element from a supported unit

The most labor-intensive task at theClass IV/V supply point is the uncrating
of mines. This requires dedicated manpower from the supported maneuver
force and the tools needed to break shipping bands and uncrate the mines
from their containers. Another important aspect of uncrating mines is
tracking fuses and booster charges. As the mines are uncrated, fuses and
booster charges are separated. However, the same number and type of fuses
and booster charges must be task-organized with minefield packages. This
requires strict supervision; mistakes can quickly lead to confusion and a waste
of emplacement time.

Because of the assets involved at a Class IV/V supply point, a TF is normally
capable of operating only one supply point at any given time. If theTF sector
is extremely wide or deep, several supply points may be planned; however,
only one can be operated at a time, based on the commander's priorities for
obstacle emplacement.

2-42 Mine-Warfare Principles

Mine Dump

FM 20-32

A mine dump is the most forward mine resupply node. It is where mines are
task-organized into mine-strip packages and then inspected, prepared, and
loaded onto emplacing vehicles. A mine dump is not a permanent supply
point, and it is not always used. Its use depends on the method of minefield
resupply, and these techniques are discussed in more detail later in this
chapter. When used, one mine dump supports a single obstacle group. It is
activated or deactivated upon initiation and completion of the obstacle group's
emplacement. Mine-dump operations are primarily an engineer company or
platoon responsibility. However, it is a good technique to augment mine-dump
operations with personnel from the companyAeam overwatching the obstacle
group being emplaced. A mine dump may be located in the vicinity of the
company/team position or closer to the obstacle group.

There are three critical tasks that must be accomplished at the mine dump:

• The minefield packages are further task-organized into mine-strip
packages (complete with the right number, type, and mix of fuses and
boosters) as they are transported to the mine dump. For example, if a
platoon is emplacing a standardized disrupt row minefield, mines are
task-organized into three mine-strip packages. As the engineer
platoon moves to the mine dump to resupply, each emplacing vehicle
loads a designated mine-strip package.

• The mines are prepared for emplacement; but they are not fused at
the mine dump. Preparation includes loosening and greasing fuse and
booster wells and ensuring proper functioning of the mine.

• The mines aretransloaded onto emplacing vehicles or a mine-delivery
system.

Transportation of mines from the Class I VTV supply point to the mine dump is
a supported TF responsibility. However, it is normally shared between the
engineer company and theTF, since neither one has the haul capability to
simultaneously service all active mine dumps.

Resupply Rules

The foil owing rules govern mine resupply:

• Mines should be uncrated at the Class I V7V supply point to preserve
transportation assets going forward.

• Mines are task-organized into minefield packages at the Class W//V
supply point.

• Transportation from the Class I VTV supply point to the mine dump is
a shared engineer and maneuver unit responsibility when a mine
dump is used.

• Mines are inspected and prepared at the last supply node (Class I VTV
supply point or mine dump) before they are loaded onto an emplacing
vehicle or a mine-delivery system.

Mine-Warfare Principles 2-43

FM 20-32

Class IV/V supply points are set up using authorized ammunition
procedures and distance requirements.

Supply Location

Consider the following when selecting a location for the Class IV/V supply
point or the mine dump:

• Carrying capacity. The location of key supply nodes and the type of
resupply method used depends in part on the type, amount, and
availability of haul assets. The carrying capacity plays a large role. In
short, the more material a vehicle can carry, the more turnaround
time you can afford. Table 2-8 provides the mine haul capacity for
various types of vehicles.

• Traffic circuit. Vehicles must be able to enter, load, unload, and exit
without interfering with the loading and unloading of other vehicles.

• Camouflage and cover. Protection from observation and thermal
imaging is desired. Protection from artillery and air attack should be
considered. Residue must be removed.

• Defense. The site must be organized for defense against enemy patrols
and saboteurs.

• Time. Time factors for handling the obstacle material, to include all
unloading, uncrating, inspecting, and loading, must be considered.

• Operators. Leaders and soldiers must be specifically allocated to
operate CI ass IV/V supply points and mine dumps. They will probably
remain there until the task is complete. The supply node may have to
be collocated with or be near a source of manpower. Table 2-7, page 2-42,
provides general guidance on how much manpower is required to
sustain mine resupply operations.

Resupply Methods

Supply Point

The methods for obstacle material resupply are—

• Supply point.

• Service station.

• Tailgate.

In each method, corps or division transport delivers Class IV/V supplies
forward to a designated Class IV/V supply point in each TF sector. The
primary differences in the methods are how the material is delivered from the
Class IV/V supply point to the obstacle location and whether or not mine
dumps are established.

The supply-point method (Figure 2-21, page2-46) requires that the emplacing
engineer platoon return totheClass IV/V supply point each time it resupplies.
This method does not require a separate mine dump. In effect, it moves the
normal tasks associated with a mine dump to the supply point. Mines are
prepared and inspected at the supply point as they are being loaded onto an
emplacing vehicle or a mine-delivery system.

2-44 Mine-Warfare Principles

C2, FM 20-32

Table 2-8

. Class IV/V haul capacity

Vehicle

Concertina
Wire 1

0)

0)

0)

0)
2 0.

<

<

CO

S "
Q. .E

o s

o

E. <u

MICLIC
Reload 2

4-«

o

c

o

X

HMMWV
1,124 kg, 6 cu m

2

51

34

27

55

56

15

1

NA

1

M35 2 1 / 2 -ton truck
2,250 kg, 12.5 cu m

4

102

69

55

111

113

30

2

2

2

M1078 2 1 /2-ton truck
2,250 kg, 13.4 cu m

4

102

69

55

111

113

30

2

2

2

M54 5-ton truck
4,500 kg, 13.6cu m

7

204

138

109

222

227

61

5

3

5

M1083 5-ton truck
4,500 kg, 15.6cu m

8

204

138

109

222

227

61

5

3

5

M930 5-ton dump truck
(without sideboards)
4,500 kg, 3.8 cu m

2

112

64

32

168

71

23

3

2

2

M930 5-ton dump truck
(with sideboards)
4,500 kg, 8.2 cu m

4

204

138

70

222

153

51

5

3

4

M1090 5-ton dump truck
4,500 kg, 3.8 cu m

2

112

64

32

168

71

23

3

2

2

HEMTT truck
9,000 kg, 15cu m

8

408

277

128

444

317

94

10

7

8

12-ton S&T

10,800 kg, 24.5 cu m

13

489

333

208

533

514

148

12

9

13

40-ton lowboy
36,000 kg, 49.3 cu m

27

1,466

1,035

419

1,777

1,035

308

30

27

27

M548 cargo
5,400 kg, 14.9 cu m

8

244

166

125

266

272

74

6

4

6

M1077PLS flat rack
14,900 kg, 17.6cu m

9

440

352

164

586

293

110

11

9

9

No of mines per box

NA

1

2

4

4

90

21

240

NA

30

Weight per box (kg)

531

22

33

41

21

20

73

833

1,195

810

Size of box (cu m)

1.8

0.04

0.05

0.12

0.03

0.06

0.16

1.6

1.8

1.8

n The number of concertina = bundles; 1 bundle = 40 rolls
2 Line charge + rocket

Several considerations may drive the use of supply-point resupply First, if
there are no additional haul assets to transport obstacle material forward
from the Class IV/V supply point, the supply-point method may be the only
viable technique. Secondly, the minefield group may be close enough to the
supply point that any other method is less efficient.

• Advantages.

— Minimizes unloading and loading of material.

— Requires minimal augmentation of haul assets.

Mine-Warfare Principles 2-45

FM 20-32

Class IV/V supply
point (mines)

Entrance

tr

S4/engineer
representatives

Exit

l E Corps/division truck

| | Received mine

(gill Task-organized mine

™™ package

I) Emplacing vehicle

Service Station

Figure 2-21. Supply-point resupply method

— Allows manpower and equipment to be massed at a single supply
point.

— Streamlines C 2 of material.
Disadvantages.

— Requires more movement of the platoon, which may take away
from emplacement time.

— Requires that the platoon move in and out of the area where the
minefields are being emplaced, increasing the risk of fratricide.

— May disrupt the emplacement of individual obstacles when
emplacing vehicles cannot carry enough material to start and
complete the obstacle. This causes emplacing vehicles to stop
work, reload, and pick up where they left off.

— Requires a larger Class IV/V supply point that is capable of
receiving mass quantities of obstacle material and multiple
loading platoons simultaneously.

The service-station method (Figure 2-22) centers on the activation of a mine
dump forward of the Class IV/V supply point. The mines are transported to a
mine dump using a combination of engineer and TF haul assets that are
normally under the control of the emplacing engineer. At the mine dump,
material is stockpiled and prepared by the mine-dump party. Obstacle

2-46 Mine-Warfare Principles

FM 20-32

material is further task-organized into minefield and mine-strip packages.
The emplacing platoon moves to a mine dump to resupply emplacing vehicles
or dispensers. Once the obstacle group is emplaced, the mine dump is
deactivated or moved to support another obstacle group.

Class IV/V supply
point (mines)

Corps/division truck

Battalion/engineer truck

Received mine

Task-organized mine package

Task-organized mine-strip
package

Emplacing vehicle

Figure 2-22. Service-station resupply method

There are several considerations for using the service-station method. First, it
is used when the obstacle group is located too far from the Class IV/V supply
point to allow efficient turnaround. Since this method provides for prestocking
obstacle material forward, it is used when available haul assets have a
relatively small capacity. This requires making frequent, short-duration
resupply trips and stocking mines to keep pace with emplacement. It also
streamlines emplacement si nee there is an opportunity to task-organize the
mines into mine-strip packages, based on the emplacement method and the
type of minefield. Finally, while it still requires the emplacing platoon to stop
laying and resupply, it minimizes the distance and the amount of time the
platoon must travel to reload. This requires that a small party be left at the
minefield to help pick up where emplacement stopped.

• Advantages.

Mine-Warfare Principles 2-47

FM 20-32

Tailgate

— Allows prestockage of obstacle material to keep pace with
emplacement.

— Minimizes the distance and the amount of time the emplacing
platoon must travel to reload.

— M ay provide additional manpower and security if it is located near
a company/team.

• Disadvantages.

— Requires additional loading and unloading of obstacle material.

— May require augmentation with haul assets.

— Disrupts emplacement by requiring the emplacing platoon to stop
obstacle emplacement, move to the supply point, reload, and
return to the minefield.

The tailgate resupply method (Figure 2-23) transports obstacle material
directly from the Class I V/V supply point to the emplacing platoon at the
obstacle site. Obstacle material is transported with TF and engineer haul
assets. Obstacle material is transloaded by emplacing engineers to emplacing
vehicles or dispensers at the obstacle site.

Class IV/V supply
point (mines)

Entrance ps/l S4/engineer

representatives

D

D

Exit

Corps/division truck

1 p Battalion/engineer truck

I I Received mine

Task-organized mine package

Q. Emplacing vehicle

Figure 2-23. Tailgate resupply method

2-48 Mine-Warfare Principles

FM 20-32

Two overriding considerations drive the decision to use the tailgate resupply
method. First, if obstacle emplacement is being conducted during limited
visibility, the tailgate method is the primary resupply method. It minimizes
disruption of emplacement and the chance of fratricide as engineers move
back into the work area after reloading. Secondly, tailgate resupply is the
primary method used when establishing a hasty defense or when the situation
is unclear and an attack can happen at anytime. Since obstacle material
remains loaded until transferred to an emplacing vehicle, the tailgate method
enables engineers to quickly break contact without risking a loss of obstacle
material to the enemy. The tailgate resupply method is the preferred method
for light forces.

• Advantages.

— Minimizes loading and unloading of obstacle material.

— Allows engineers to break contact rapidly in the event of enemy
attack without losing obstacle material to the enemy.

— Minimizes the movement of platoons in and out of the minefield
(suitablefor limited visibility).

• Disadvantages.

— Requires augmentation by high-capacity transportation assets
that are capable of offsetting the loss in turnaround time if the
vehicle has to wait at the obstacle site.

— May result in inefficient use of haul assets.

— Complicates C 2 in linking mine transport assets with emplacing
engineers si nee the engineers continue emplacement.

— Causes task-organizing of minefield packages to be conducted
concurrently with loading.

MINEFIELD MARKING

Criteria

M inefields must be marked to prevent fratricide. Marking ensures that
friendly soldiers do not accidentally enter a minefield, and it is a requirement
under STANAGs and Geneva Convention agreements. When emplacing
minefields behind theforward line of own troops (FLOT) (in the main battleor
rear area), mark the minefields on all four sides. This includes air-delivered
Volcano minefields that are sited and emplaced before the enemy attacks.

Gator, RAAM, and ADAM minefields are exceptions to the rule. To preserve
the system's flexibility and because of the relative inaccuracy of emplacement,
these minefields are not normally marked before emplacement unless the
tactical situation permits. M arking the area where mines are to be emplaced
by artillery or fixed-wing aircraft is not recommended. Mines could likely be
emplaced outside the marked area.

Forward of the FLOT, minefields are not generally marked before
emplacement. However, commanders must make every attempt to mark these
minefields as soon as the tactical situation allows. For scatterable minefields,

Mine-Warfare Principles 2-49

FM 20-32

Perimeter

Techniques

a commander may choose to remove markings once the self-destruct (SD)time
of the mines has expired; but the location of the minefield must still be
recorded and forwarded to higher and adjacent units in case some of the mines
did not self-destruct.

Construct a perimeter fence (Figure 2-24) to mark a minefield. Start
emplacing the perimeter fence before emplacing mines, preferably during site
layout if the tactical situation permits. For conventional minefields, ensure
that the perimeter fence is at least 15 meters outside the nearest mine or
cluster. For scatterable minefields, the area inside the perimeter fence must
include the safety zone. (See Chapter 3 for more details.)

Place warning signs for areas containing emplaced mines. Space the warning
signs 10 to 50 meters apart, depending on the terrain. If using pickets and
barbwire to mark the minefield, ensure that the wire is waist-high. If using
concertina wire, use a one-roll height. Place additional strands of barbwire or
rolls of concertina at the discretion of the commander.

A commander may decide to mark individual minefields in an obstacle group
or to mark the group as a whole (Figure 2-25, page 2-52). Depending on the
size and the location of minefields, either technique may have the advantage
of using fewer resources or labor. Normally, marking individual minefields in
a fix-obstacle group requires less resources than marking the entire obstacle
group. The opposite is usually true for disrupt-, turn-, and block-obstacle
groups. The decision to mark individual minefields or obstacle groups should
not be based solely on logistical considerations. A commander must consider
the amount of tactical and/or sustainment movement required in and around

the obstacle groups as well as the capability of the unit's C 2 forces.

The following advantages and disadvantages to marking individual minefields
versus marking the obstacle group are provided to help commanders make the
best decision.

Marking Individual Minefields

• Advantages.

— Returning units forward of the minefields have more routes
(tactical lanes or bypasses) through the obstacle group.

— Tactical lanes need only pass through individual minefields.

— Mine recovery i s easi er.
• Disadvantages.

— Obstacle may not provide the desired effect.

— Enemy units can more easily bypass individually marked
minefields in a fix- or block-obstacle group.

Marking Obstacle Groups

• Advantages.

2-50 Mine-Warfare Principles

FM 20-32

28 cm

-► Red

White

Warning sign for areas containing mines

- >• y- -a "J 'A >■ -a y= -a y- y- y- y- y- y- m y- 'a y- y-

Hv x li,v,

'Y /

\ I

Barbwire fencing for a minefield

Concertina fencing for a minefield

Figure 2-24. Minefield marking

— Obstacle is more likely to provide the desired effect.

— The enemy cannot easily discern individual minefields and decide
when to employ breach assets in a fix-or block -effect minefield.

Disadvantages.

— Friendly patrols cannot clearly see if the minefield is tampered
with unless they are within the perimeter fence.

Mine-Warfare Principles 2-51

FM 20-32

Obstacle
Effect

Individual Minefield

Obstacle Group

Disrupt

□

- i

Turn

Fix

Block

Figure 2-25. Marking of minefields and obstacle groups

— Tactical lanes need to pass through the entire obstacle group.
Friendly units passing through the lanes will be slowed
considerably.

MINEFIELD TURNOVER

Once an obstacle group is completed, theemplacing unit conducts minefield or
obstacle turnover with the owning unit. Occasionally, the owning unit will
transfer responsibility for a minefield to another unit. Minefield or obstacle
turnover ensures that the commander of the owning unit is familiar with the
minefield and understands his responsibilities concerning it. Turnover is
conducted whether or not there are lanes/gaps to be closed. Minefield turnover
is a must; the time and the location for the turnover is established during the
initial siting coordination.

The engineer must verbally address the following items with the
overwatching company/team:

• Intelligence.

— Provide an update on enemy activity forward of the minefield.

2-52 Mine-Warfare Principles

FM 20-32

— Discuss expected enemy reconnaissance efforts.

— Brief on local, friendly, and enemy situations.
Maneuver.

— Discuss obstacle protection against enemy dismounted patrols.
Recommend that the maneuver unit conducts security/patrols to
protect the minefield during limited visibility.

— Discuss fire control measures.
M obi I ity/su rvi vabi I ity

— Discuss the obstacle's intended effect on enemy maneuver.

— Discuss the minefield front and depth and walk/ride the minefield
trace. Provide grid coordinates of the minefield trace.

— Discuss minefield composition.

— Discuss friendly minefield marking.

— Discuss lane/gap closure, if applicable. Confirm the signal or the
activity that initiates lane closure.

— Train units on how to close lanes. This may mean training the unit
on emplacing conventional mines or using the M OPM S.

Fire support.

— Update the company FIST on grid coordinates for the minefield
trace.

— Discuss indirect fires covering the minefield.

CSS. Provide mines/material required to close lanes/gaps and ensure
that all necessary material is available and prepared.

C 2 .

— Transfer graphics and documentation (minefield records,
demolition-target folders, or other written records).

— Report completion of the turnover to the higher engineer and
supported unit headquarters.

— Complete an obstacle-turnover report (a sample work sheet is
shown in Figure 2-26, page 2-54) and submit it to higher
headquarters.

— Forward the written minefield report and record (DA Form 1355 or
1355-1-R) to the next higher commander common to both units.

Mine-Warfare Principles 2-53

FM 20-32

OBSTACLE-TURNOVER/TRANSFER REPORT

OBSTACLE DATA

Obstacle Number

Obstacle Type

Emplacing Authority

Obstacle Location (8-digit UTM
grid to center of mass)

Obstacle Effect

Emplacing Unit

TURNOVER DATA

Transferring Unit

Receiving Unit

Date/Time of Transfer

Next Higher Command Common to Both

Date Obstacle Emplaced

TURNOVER CHECKLIST

□ Intelligence.

Enemy activity forward of the obstacle (discuss enemy recon and breaching efforts).

Friendly activity in the vicinity of the obstacle (discuss LOGPAC, recon, counterrecon maneuver).

Maneuver.

• Obstacle protection against enemy recon/breaching (discuss overwatch, counterrecon patrols, sunrise
sweep).

• Location of TRPs and indirect-fire targets (point out location on graphics and terrain).
Rearward/forward passage of lines (discuss planned and routine activity around the obstacle).

□ Mobility/survivability.

• Obstacle trace (discuss corner grids on map and point them out on terrain).
Obstacle marking (rear side, all four sides, fence, signs, HEMMS poles, or no marking).

• Obstacle composition.

• Location of gaps/lanes.

• Method of closing gaps/lane (MOPMS, ADAM, RAAM, conventional mines).

• Location of material to close gaps/lanes.

□ CSS. Planned casualty evacuation and supply routes in the vicinity of the obstacle.

□ C d

transferred to receiving unit.

DA Form 1 355 or 1 355-1 -R, dated

Obstacle overlay, dated , transferred to receiving unit.

Target folder, dated , preparing headquarters , transferred to receiving unit.

Higher headquarters (transferring, receiving, and emplacing units) notified of transfer.

DA Form 1 355 or 1 355-1 -R forwarded. (NOTE: Three copies are required for transfer — one to

transferring unit, one to receiving unit, and one to next higher headquarters common to both.)

CERTIFICATION

The undersigned certify that the receiving unit has assumed full responsibility for the obstacle indicated
above. The unit commander understands all the information related to the obstacle, the obstacle intent, and
his responsibility to transfer or recover the obstacle upon his departure.

Signature of Transferring Unit Commander

Signature of Receiving Unit Commander

Printed Name and Rank

Printed Name and Rank

Figure 2-26. Sample obstacle-turnover work sheet

2-54 Mine-Warfare Principles

FM 20-32

MINEFIELD INSPECTION AND MAINTENANCE

Mines left in the ground for a long time may deteriorate and malfunction for
one or more of the following reasons:

• Moisture may have entered the igniter or the body of the mine and
either neutralized the explosive or corroded the metal parts. Such
actions may be aggravated by local factors (soil acidity or wide
temperature swings).

• Frost or heat may have subjected the mine to mechanical strain and
caused distortion.

• I nsects or vegetation may have caused obstructions.

• Animals may have turned mines over or detonated them.

Technical inspections should only be made by experienced engineers or
explosive ordnance disposal (EOD) personnel. When a minefield deteriorates
below the operating level, additional mine strips/rows are added to restore its
effectiveness. They are sited to the front or the rear of the existing minefield to
increase its depth. New mine strips/rows are treated as separate minefields.

Technical inspections of minefields are normally done at three-month
intervals. They are done more frequently during extreme weather conditions.
Detailed information on mine inspections can be found in Technical Manual
(TM) 9-1345-203-12.

Mine-Warfare Principles 2-55

FM 20-32

2-56 Mine-Warfare Principles

This chapter implements STANAG 2990.

Chapter 3

Scatterable Mines and Mine Delivery Systems

SCATM I N Es are laid without regard to a classical pattern. They are
designed to be delivered or dispensed remotely by aircraft, artillery,
missile, or a ground dispenser. All US SCATMINEs have a limited active
life and self-destruct after that life has expired. The duration of the active
I ife vari es with the type of mi ne and the del i very system.

SCATM I NE systems enable a tactical commander to empl ace minefields
rapidly in enemy-held territories, contaminated territories, and in most
other areas where it is impossible for engineers to empl ace conventional
minefields. Some systems allow for rapid emplacement of minefields in
friendly areas. As with all minefields and obstacles, scatterable minefields
are an engineer responsibility.

Based on the tactical plan, the maneuver commander's staff engineer
determines the minefield location, size, density, and emplacement and SD
times. With this information and a thorough understanding of the
available systems, he can then recommend the type of minefield
(conventional or scatterable) to be emplaced. If a scatterable minefield is
selected, he recommends the delivery system and coordinates the
minefield with appropriate staff officers.

GENERAL CHARACTERISTICS

Most US SCATMINEs have similar characteristics. SCATMINEs are much
smaller in size and weight than conventional mines. For example, a standard
AT SCATM I NE weighs approximately 1.8 kilograms and has 600 grams of
explosive; an M 15 conventional mine weighs 13.5 kilograms and has 10
kilograms of explosive. Arming mechanisms, arming times, and SD times of
SCATMINEs differ based on the dispensing system.

Antipersonnel Mines

There are two general categories of A P SCATM I NEs— wedge-shaped and
cylindrical (Figure 3-1, page 3-2). Table 3-1, page 3-2, summarizes the
characteristics of each AP SCATM I N E .

Scatterable Mines and Mine Delivery Systems 3-1

C2, FM 20-32

12 cm

6 cm

Cover Trip-wire S&A mechanism
port

Main
charge

Booster
pellet

>\Fragmenting
body

Trip-wire
port

Figure 3-1. AP SCATMINEs

Table 3-1. Characteristics of AP SCATMINEs

Mine

Delivery
System

DODIC

Arming
Time

Fuse

Warhead

AHD

SDTime

Explosive
Weight

Mine
Weight

Number
of Mines

M67

155-mm

artillery

(ADAM)

D502

Within 1
min after
ground
impact

Trip
wire

Bounding
frag

20%

4hr

21 g
Comp A5

540 g

36 per

M731

projectile

M72

155-mm

artillery

(ADAM)

D501

Within 1
min after
ground
impact

Trip
wire

Bounding
frag

20%

48 hr

21 g

Comp A5

540 g

36 per

M692

projectile

BLU 92/B

USAF
(Gator)

K291
K292
K293

2 min

Trip
wire

Blast frag

1 00%

4hr
48 hr
15 days

540 g
Comp B4

1 .44 kg

22 per
CBU 89/B
dispenser

M77

MOPMS

K022

2 min

Trip
wire

Blast frag

0%

4hr
(recycle
up to 3
times)

540 g
Comp B4

1 .44 kg

4 per
M131
dispenser

Volcano

Ground/

air

K045

2 min

Trip
wire

Blast frag

0%

4hr
48 hr
15 days

540 g
Comp B4

1 .44 kg

1 per M87
canister

3-2 Scatterable Mines and Mine Delivery Systems

FM 20-32

The M67 and M72 AP SCATMINEs are wedge-shaped and dispensed from an
ADAM projectile, which is a special 155-millimeter artillery munition. Each
mine weighs 540 grams and is 7 centimeters high.

TheM74, BLU 92/B, M77, and Volcano AP SCATMINEs are all cylindrical in
shape. They are 6 centimeters high and 12 centimeters in diameter.
Cylindrical AP SCATMINEs kill enemy soldiers through the combined effects
of blast and fragmentation. Each mine contains 540 grams of composition B4
as its main charge. The charge detonates upon actuation and shatters the
mine's metal casing to produce shrapnel. Shrapnel is propelled upward and
outward from the mine and produces fatal casualties to a distance of 15
meters. Each mine has eight trip wires (four on the top and four on the
bottom) that deploy after ground impact up to 12 meters from the mine. Trip
wires are similar in appearance to very fine thread; they are olive-drab green
in color and weighted at the free end. A tension of 405 grams applied to one
trip wire is enough to create a break in the electrical circuit and cause the
mine to detonate.

Antitank Mines

All AT SCATMINEs (Figure 3-2) have similar functional characteristics. They
are cylindrical in shape, weigh approximately 1.8 kilograms, contain 585
grams of cyclonite (RDX) explosive as the main charge, and have a
magnetically induced fuse. The characteristics of each AT SCATMINE are
summarized in Table 3-2, page 3-4.

12 cm

B ° oster Clearing
char 9\ charge

S&A

mechanism

6 cm

Plate

Figure 3-2. AT SCATMINE

Scatterable Mines and Mine Delivery Systems 3-3

C2, FM 20-32

Table 3-2. Characteristics of AT SCATMINEs

Mine

Delivery
System

DODIC

Arming
Time

Fuse

Warhead

AHD

SD Time

Explosive
Weight

Mine
Weight

Number
of Mines

M73

155-mm

artillery

(RAAM)

D503

Within 1
min after
ground
impact

Magnetic

M-S plate

20%

48 hr

585 g RDX

1.7 kg

9 per
M718
projectile

M70

155-mm

artillery

(RAAM)

D509

Within 1
min after
ground
impact

Magnetic

M-S plate

20%

4hr

585 g RDX

1.7 kg

9 per
M741
projectile

BLU 91/B

USAF
(Gator)

K291
K292
K293

2 min

Magnetic

M-S plate

NA

4hr
48 hr
1 5 days

585 g RDX

1.7 kg

72 per
CBU 89/B
dispenser

M76

MOPMS

K022

2 min

Magnetic

M-S plate

NA

4hr
(recycle
up to 3
times)

585 g RDX

1.7 kg

17 per

M131

dispenser

Volcano

Ground/
air

K045

2 min
30 sec

Magnetic

M-S plate

NA

4hr
48 hr
1 5 days

585 g RDX

1.7 kg

5 per M87
canister; 6
per

M87A1
canister

AT SCATMINEs are designed to produce a K-Kill instead of an M -K ill . They
produce a kill by using an SFF warhead (created from an M-S plate). The
warhead penetrates the vehicle's belly armor, and spalling metal from the
vehicle (caused by the mine blast) kills occupants instantly. Even though the
crew is killed, the drive train may be undamaged and the vehicle may
continue to move. On enemy tanks with autoloaders, the detonation of rounds
in the belly-mounted ammunition carousel is very likely. The mine may not
achieve a kill when the track of an armored vehicle runs directly over it.

The magnetic fuse is designed to detonate as the magnetic field changes over
the mine. The warhead is bidirectional, meaning that it can fire from the top
or the bottom. AHDs are built into 20 percent of M70, M73, and M75 mines.
Although Volcano, M76, and BLU 91/B mines do not have AHDs, they may
detonate when moved, because the mine may sense a significant change from
its original orientation.

Due to their small size, the reduced explosive, and the possibility of landing
with an improper orientation (on their side or at an angle), AT SCATMINEs
have less chance of destroying a vehicle than a conventional full-width AT
mine. An armored vehicle will not always be destroyed after an encounter
with an AT SCATMINE. Further, the effectiveness of SCATMINEs in water
obstacles is reduced even more, because 5 centimeters of water prevents the
formation of the M-S slug. Although the blast wave is accentuated by
underwater placement (attacking hatches and covers), mining of banks and
approaches is recommended instead.

3-4 Scatterable Mines and Mine Delivery Systems

C2, FM 20-32

CAPABILITIES

Faster Response

SCATMINEscan beemplaced more rapidly than conventional mines, so they
provide a commander with greater flexibility and more time to react to
changes in situations. The commander can use SCATMI NEs to maintain or
regain the initiative by acting faster than the enemy. Using SCATMI NEs also
helps preserve scarce mine resources.

Remote Placement

All SCATMI NEs are remotely emplaced. This enhances battlefield agility and
allows the maneuver commander to emplace mines rapidly to best exploit
enemy weaknesses. SCATMINEscan be used as situational obstacles or to
attack enemy formations directly through disrupt, fix, turn, and block
obstacles. Modern fusing, sensing, and AHDs allow SCATM I NEs to better
defeat enemy attempts to reduce the minefield.

Increased Tactical Flexibility

Efficiency

Upon expiration of the SD time, the minefield is cleared and the commander
can move through an area that was previously denied to enemy or friendly
forces. I n many cases, the SD period may be set at only a few hours. This
feature allows for effective counterattacks tothe enemy's flank and rear areas.

SCATM I N Es can be emplaced by a variety of delivery methods. They can be
deployed by fixed-wing aircraft, helicopters, artillery, manpack, or ground
vehicles. They satisfy the high mobility requirements of modern warfare.
Manpower, equipment, and tonnage are reduced for their emplacement.

Increased Lethality

AT SCATM I NEs utilize an SFF that is created from two M-S plate charges to
produce a full-width kill. In simple terms, a metal plate is formed into a high-
velocity slug that punches a hole in the belly of a tank. The effect produces an
M-Kill against the vehicle's engine, track, or drive train; or it produces a K-
Kill when the on-board ammunition is set off and the crew is killed or
incapacitated or the vehicle's weapon system is destroyed. AT SCATM I NEs
are designed to destroy any tank in the world. I n order to form an SFF, the
mine requires a certain standoff between the vehicle and the target. Mines
must also be nearly perpendicular to the target (laying on either side). The
M -S plate i s actual ly two pi ates— one faci ng the top of the mi ne and one faci ng
the bottom. This ensures that it will successfully attack the target while lying
on either side.

AP SCATM I NEs are actuated by a trip wire and utilize a blast-fragmentation
warhead.

LIMITATIONS

Extensive Coordination

Because SCATM I NEs area very dynamic weapon system, great care must be
taken to ensure that proper coordination is made with higher, adjacent, and

Scatterable Mines and Mine Delivery Systems 3-5

C2, FM 20-32

subordinate units. To prevent friendly casualties, all affected units must be
notified of the location and the duration of scatterable minefields. Recording
and reporting procedures for SCATMINEs are discussed in detail in Chapter 8,
and they were specifically designed to minimize friendly casualties.

Proliferation of Targets

Visibility

Accuracy

Orientation

LIFE CYCLE

SCATM I NEs may be regarded by some commanders as easy solutions to
tactical problems. Target requests must be carefully evaluated, and a priority
system must be established because indiscriminate use of weapon systems
will result in rapid depletion of a unit's basic load. Controlled supply rates
(CSRs) will probably be a constraint in all theaters.

SCATMINEs are highly effective, especially when fires and obscurants strain
the enemy's C 2 . SCATM I NEs lay on the surface of the ground, but they are
relatively small and have natural coloring.

SCATM I NEs cannot be laid with the same accuracy as conventional mines.
Remotely delivered SCATMINE systems areas accurate as conventional
artillery-delivered or tactical aircraft-delivered munitions.

Between 5 and 15 percent of SCATMINEs will come to rest on their edges;
mines with spring fingers will be in the lower percentile. If there is mud or
snow more than 10 centimeters deep, the number will be in the higher
percentile. When employing ADAMs or RAAMs in more than 10 centimeters
of snow or mud, high-angle fire should be used and the number of mines
increased. AP mines may be less effective in snow, because the deployment of
tripwires is hindered. Melting of the snow may also cause the mines to change
positions and activate AH Ds.

All SCATM I NEs have a similar life cycle, although specific times vary based
on theSD time and the dispensing system.

For safety reasons, SCATMINEs must receive two arming signals at launch.
One signal is usually physical (spin, acceleration, or unstacking), and the
other is electronic. This same electronic signal activates the mine's SD time.

M ines start their safe-separation countdown (arming time) when they receive
arming signals. This allows the mines to come to rest after dispensing and
allows the mine dispenser to exit the area safely. Table 3-1, page 3-2, and
Table 3-2, page 3-4, show arming times for individual SCATMINEs.

Mines are armed after the arming time expires. The first step in arming is a
self-test toensure proper circuitry. Approximately 0.5 percent of mines fail the
self-test and self-destruct immediately.

After the self-test, mines remain active until their SD time expires or until they
are encountered. M ines actually self-destruct at 80 to 100 percent of their SD
time. The time period from when the mines begin to self-destruct and when they

3-6 Scatterable Mines and Mine Delivery Systems

C2, FM 20-32

finish is called theSD window (Table 3-3). No mines should remain active after
theSD time has been reached. Two to five percent of US SCATMINEsfail to self-
destruct as intended. Any mines found after the SD time must be treated as
unexploded ordnance (UXO). For example, mines with a 4-hour SD time will
actually start self-destructing at 3 hours and 12 minutes. When the 4-hour SD
time is reached, no unexploded mines should exist.

Table 3-3. SD windows

SD Time

SD Window Begins

4 hours

3 hours 12 minutes

48 hours

38 hours 24 minutes

5 days

4 days

1 5 days

1 2 days

LETHALITY AND DENSITY

Lethality and Tactical-Obstacle Effect

Scatterable minefields are employed to reduce the enemy's ability to
maneuver, mass, and reinforce against friendly forces. They increase the
enemy's vulnerability to fires by producing specific obstacle effects (disrupt,
fix, turn, and block) on the enemy's maneuver. To achieve this aim, individual
minefields must be emplaced with varying degrees of lethality. During
emplacement, lethality is varied primarily by changing the minefield density.
Therefore, there is a direct correlation between the obstacle effect and the
minefield density. I n order to achieve the tactical-obstacle effect, use the
following guidance when selecting minefield density:

Disrupt.

— Low density.

— Probability of encounter: 40 to 50 percent.

— L i near density: 0.4 to 0.5 mi ne per meter.

• Fix.

— Medium density.

— Probability of encounter: 50 to 60 percent.

— L i near density: 0.5 to 0.6 mi ne per meter.

• Turn.

— High density.

— Probability of encounter: 75 to 85 percent.

Scatterable Mines and Mine Delivery Systems 3-7

FM 20-32

Density

— Linear density: 0.9 to 1.1 mines per meter.
Block.

— High density.

— Probability of encounter: 85+ percent.

— Linear density: More than 1.1 mines per meter.

Density is normally expressed as linear or area. For conventional mines,
linear density is normally used and is expressed in the average number of
mines per meter of minefield front. For SCATMI NE systems, area density is
normally used and is expressed as the average number of mines per square
meter. SinceSCATMINE systems normally employ a preset combination of AT
and AP mines, the area density includes both. For example, a scatterable
minefield with an area density of 0.006 mine per square meter may have an
AT density of 0.004 AT mine per square meter and an AP density of 0.002 AP
mine per square meter. Due to the varying dimensions of scatterable
minefields that can be created by the different types of employment devices,
the exact density of a scatterable minefield cannot be determined. However,
an estimate of the average density can be determined by using the following
formulas:

• Linear density equals the number of mines divided by the minefield
front.

number of mines

= mines per meter

minefield front

Area density equals the number of mines divided by the minefield
area.

number of mines

— — ; — = mines per square meter

front x depth

Area density can be converted to linear density by multiplying the
area density by the minefield depth. (NOTE: Converting area
density to linear density is not always accurate due to the
space between minefield strips.)

area density x minefield depth= linear density

EXAMPLE: A 650- by 200-meter Gator minefield contains 564 mines (432 AT
and 132 AP).

• Area density: 564 -^(200 x 650) =0.004 mine per square meter.

— AT area density: 432 -M200 x 650) =0.003 mine per square meter.

3-8 Scatterable Mines and Mine Delivery Systems

FM 20-32

— AP area density: 132 -M200 x 650) =0.001 mine per square meter.
• L i near density: 564 -5- 650 = 0.87 mi ne per meter.

— AT I i near density: 432 -5- 650 = 0.67 mi ne per meter.

— AP linear density: 132 -^650 =0.2 mine per meter.

COMMAND AND CONTROL

Due to the delivery means, C 2 of SCATM I N Es is more complex than
conventional mines. SCATM I NEs are very dynamic weapon systems because
they can be rapidly emplaced and then cleared via their SD capability. Also,
the physical boundary of a scatterable minefield is not clearly defined. These
characteristics require impeccable communications and coordination to
ensurethat all friendly units know where mines are located, when they will be
effective, and when they will self-destruct.

AUTHORITY

The corps commander has emplacement authority for all scatterable
minefields within the corps AO. He may delegate this authority to lower
echelons according to the guidelines contained in Table 3-4.

Table 3-4. Emplacement authority

System Characteristics

Emplacement Authority

Ground- or artillery-delivered, with SD time greater
than 48 hours (long duration)

The corps commander may delegate emplacement
authority to division level, who may further delegate
it to brigade level.

Ground- or artillery-delivered, with SD time of 48
hours or less (short duration)

The corps commander may delegate emplacement
authority to division level, who may further delegate
it to brigade level, who may further delegate it to TF
level.

Aircraft-delivered (Gator), regardless of SD time

Emplacement authority is normally at corps,
theater, or army command level, depending on who
has air-tasking authority.

Helicopter-delivered (Volcano), regardless of SD
time

Emplacement authority is normally delegated no
lower than the commander who has command
authority over the emplacing aircraft.

MOPMS, when used strictly for a protective
minefield

Emplacement authority is usually granted to the
company, team, or base commander. Commanders
at higher levels restrict MOPMS use only as
necessary to support their operations.

Based on how the commander wants to shape the battlefield, he must
specifically delegate or withhold the authority to employ SCATM I N E systems.
The commander's guidance concerning SCATM I NEs is found in the unit's
OPORD/operation plan (OPLAN). Additional information is included in their
engineer and fire-support annexes, if used.

Due to the complete control a commander has over the MOPMS, emplacement
authority guidelines do not apply to the MOPMS. It is impractical for the

Scatterable Mines and Mine Delivery Systems 3-9

FM 20-32

corps or brigade commander to authorize every MOP MS protective minefield.
Therefore, authority to empl ace MOPMS minefields is specifically delegated.
In general, units can emplace MOPMS protective minefields as required for
their own self-defense and report them as they do any protective obstacle. Any
MOPMS minefield used as part of an obstacle plan must be reported as a
scatterable minefield.

COORDINATION

Basic responsibilities of key commands, staff elements, and units are outlined
in Table 3-5. The fire-support coordinator (FSCOORD) is involved in planning
artillery-delivered (ADAM and RAAM) SCATMINEs, and the air liaison
officer (ALO) is involved in planning air-delivered (Gator and Volcano)
SCATM I N Es. The engineer has primary responsibility for planning and
employing SCATM I NE systems. It is vital that coordination be conducted with
all units and subunits that will be effected by the employment of
SCATMINEs. A scatterable minefield warning (SCATM IN WARN) will be sent
to all effected units before the emplacement of the minefield (seeChapter 8 for
more details).

Table 3-5. Coordination responsibilities

Element

Responsibilities

G3/S3 with Engineer
FSCOORD/ALO

Plan and coordinate the minefield location, size, composition, density, SD
time, safety zone, and emplacement time

Designate and brief the emplacing unit

Incorporate the minefield and the safety zone into the obstacle plan

Receive and forward the scatterable minefield report and record

Disseminate information concerning the minefield in the SCATMINWARN to
adjacent and subordinate units prior to laying

Post operation maps with the minefield location, safety zone, and DTG of
the SD time; and disseminate the SCATMINWARN 1 hour prior to initiation
of the SD sequence

Emplacing Unit

Calculate the logistical requirements

Calculate the safety zone

Emplace the minefield

Report the amount of ammunition expended

Prepare and forward the scatterable minefield report and record to the
authorizing commander via appropriate channels

Maneuver Units

Be aware of the calculated safety-zone boundary and advise subunits of its
location

EMPLOYMENT AND EMPLACEMENT

Employment considerations and emplacement techniques and procedures
differ for each type of SCATM I N E and delivery system. This section discusses
the characteristics of each delivery system and provides tactical
considerations for the employment of each system on the battlefield.
Techniques and procedures for emplacing minefields intended to disrupt, fix,

3-10 Scatterable Mines and Mine Delivery Systems

FM 20-32

turn, and block are also discussed; and they build on tactical-obstacle design
principles discussed in Chapter 2.

Area-Denial Artillery Munitions and Remote Antiarmor Mines

ADAMsand RAAMs a re delivered by a 155-millimeter howitzer (Figure 3-3).
There are no special modifications or adaptations necessary for the firing
system. Mines are contained within a projectile and are dispensed while the
projectile is in the air. The effective range for the M 109 howitzer is 17,500
meters, and for the M 198 howitzer, 17,740 meters.

Figure 3-3. Emplacement of ADAMs and RAAMs

The M 692 (long-duration) and the M 731 (short-duration) ADAM projectiles
deliver AP mines with different SD times. Each ADAM round contains 36
mines. The M731/M731A1 round contains M72 AP mines with 4-hour SD
times; the M692/M692A1 round contains M67 AP mines with 48-hour SD
times. SD times are preset during the manufacturing process and cannot be
changed.

The wedge-shaped ADAM is a bounding-fragmentation mine that deploys up
to seven tension-activated trip wires 6 meters away from the mine. After
ground impact, trip wires are released and the mine is fully armed. The
ADAM contains a metal -jacketed sphere that is filled with 21 grams of
composition A5 as its main charge. A liquid-explosive propelling charge
positions itself at the bottom of the sphere after impact with the ground.
When the mine is jarred or tilted, or when one of its trip wires receives a

Scatterable Mines and Mine Delivery Systems 3-11

FM 20-32

E mployment

tension of at least 405 grams, the sphere propels upward 0.6 to 2.4 meters and
detonates. The lethal casualty radius is between 6 and 10 meters.

The M741 (short-duration) and the M718 (long-duration) RAAMs are
artillery-delivered AT mines. Each RAAM round contains nine mines. The
M741/M741A1 round contains M70AT mines with 4-hour SD times; the
M718/M718A1 round contains M73AT mines with 48-hour SD times. The SD
times are preset during the manufacturing process and cannot be changed.
The RAAM mine utilizes an SFF warhead, has a magnetic-influence fuse,
weighs 1.7 kilograms, and has a small (12 centimeters in diameter by 6
centimeters in height) cylindrical shape.

The new model ADAM and RAAM mines (designated by an Al suffix) have a
45-second arming time; the older models have a 2-minute arming time. The
new model RAAM has a built-in feature that defeats magnetic, signature-
duplicating breaching devices.

The ADAM and RAAM systems were designed to provide a flexible, rapid-
response mining capability. These systems provide the maneuver commander
with the capability to emplace mines directly on top of, in front of, or behind
enemy forces. This is one of their greatest advantages. Their responsiveness
allows the mission to be executed quickly and allows the commander to
effectively influence a rapidly changing battlefield. They also allow the
commander to emplace minefields while maintaining maximum standoff from
the target. In short, their emplacement does not require committing any force
(ground or air) forward. ADAM and RAAM systems may be used for the
following purposes:

• Defense.

— Develop targets for long-range AT weapons.

— Close gaps and lanes in other obstacles.

— Delay or disrupt attacking forces.

— Deny the enemy unrestricted use of selected areas.

— Disrupt movement and commitment of second-echelon forces.

— Disrupt and harass enemy C 2 , logistics (excluding medical), and
staging areas.

— Reinforce existing obstacles.

— Disrupt or delay river crossings.

• Offense.

— Supplement flank reconnaissance and security forces to protect
flanks along AAs.

— Suppress and disrupt enemy security elements once contact has
been made.

— H i nder the withdrawal of enemy forces.

3-12 Scatterable Mines and Mine Delivery Systems

E mplacement

FM 20-32

— H i nder the abi I ity of the enemy to rei nforce the objective area.

The time and the number of rounds required to install effective ADAM s and
RAAMs limit their use. Their range is limited to 17,500 or 17,740 meters,
depending on which howitzer (M109 or M198, respectively) is used. Many of
the deep-interdiction missions that support force-projection doctrine require a
greater distance. Due to the large footprint created when the minefield is
fired, many mines will scatter outside the planned minefield area. It is
therefore necessary to plot the safety zone in order to prevent fratricide. The
fire-support element (FSE) is responsible for plotting the safety zone, and the
staff engineer should be familiar with the process and the expected results.
The staff engineer ensures that the safety zone is plotted on the tactical
command post (TCP)/TOC operation overlay.

ADAM and RAAM mining missions are requested through normal artillery-
support channels. Although the actual numbers vary based on the unit and
the mission, a representative basic load for an artillery battalion consists of
approximately 32 ADAM and 24 RAAM (short SD time) rounds per artillery
piece. NOTE : The rounds with long SD times are normally used for
preplanned targets and are issued from an ammunition supply point
(ASP) on a mission-by-mission basis.

Once the proper authorization has been received to employ the mines,
requests for ADAMs and RAAMs are processed in the same way as other
requests for fire support, including targets of opportunity. Allocate enough
time for processing the request and completing firing procedures. This ensures
that the enemy has not moved out of the target area before execution. (FM 90-
7 contains more information on this process.) The use of ADAMs and RAAMs
for preplanned fires requires close coordination among the Assistant Chief of
Staff, G3 (Operations and Plans) (G3)/Operations and Training Officer (US
Army) (S3), the staff engineer, and FSE sections. Coordination should also be
made with the S2 and the S3 during the development of the decision support
template (DST) to identify the proper named areas of interest (NAIs), target
areas of interest (TAIs), trigger points, and decision points.

There are two critical aspects when emplacing ADAM and RAAM minefields:

• Designing the minefield to achieve the required effect.

• Ensuring the technical correctness of resourcing and delivering the
minefield.

The following discussion provides general guidance for designing the
minefield to achieve the desired effect and for determining the safety zone to
assess the impact on maneuver. Appendix H of FM 6-20-40 serves as the
primary source for technically resourcing and delivering artillery-delivered
minefields.

ADAM and RAAM minefields can beemplaced to achieve disrupt, fix, turn,
and block effects based on the principles outlined in Chapter 2. The engineer
is responsible for deciding the required location, the density, the size, the
composition, and the duration of the minefield based on the tactical-obstacle
plan and the obstacle restrictions of the higher unit. The engineer provides

Scatterable Mines and Mine Delivery Systems 3-13

FM 20-32

this information to the FSE. Table 3-6 provides guidance on the minefield
density and size necessary to achieve the desired obstacle effect.

Table 3-6. RAAM and ADAM minefield density and size

Obstacle
Effect

RAAM

ADAM

Width
(meters)

Depth
(meters)

Area 1

Linear 2

Area 1

Linear 2

Disrupt

0.001

0.2

0.0005

0.1

200

200

Turn

0.002

0.8

0.001

0.4

400

400

Fix

0.002

0.4

0.0005

0.1

200

200

Block

0.004

0.6

0.002

0.8

400

400

1 Area density = mines per square meter
2 Linear density = mines per meter

Gator

The FSE determines all the technical aspects for delivering the minefield,
such as the number of rounds required per aim point, the number of aim
points required, the size of the safety zone, and the time required toemplace
mines. There is a wide variety of factors involved in determining the number
of rounds, the size of the safety zone, and the emplacement time. These factors
are the range-to-target time, the battery-to-minefield angle, the high- or low-
angle trajectory, and the method of firing (observer adjust or meteorological
data plus velocity error [Met+VE] transfer). The FSE must tell the engineer
whether the minefield mission is feasible. Feasibility is based on the number
of rounds available, the scheme of indirect fires, and the availability of
artillery tubes.

The engineer is primarily concerned with two technical aspects of delivery
provided by the FSE— the safety zone and the emplacement time. The
engineer uses the safety zone and the minefield duration to assess the impact
of the minefield on the mobility requirements of the scheme of maneuver. The
engineer depicts the safety zone on the obstacle overlay. He also uses the
safety zone to identify requirements for minefield marking if theunit leaves or
turns over the area before the SD time. The engineer and the FSE use the
emplacement time to synchronize the delivery of the minefield with the
tactical plan.

The Gator (Figure 3-4) has a longer range than any other SCATMINE system.
It provides a means to rapidly emplace minefields anywhere that can be
reached by tactical aircraft. The Gator is produced in two versions— the
United States Air Force (USAF) CBU-89/B system that contains 94 mines (72
AT and 22 AP) per dispenser and the United States Navy (USN) CBU-78/B
system that contains 60 mines (45 AT and 15 AP) per dispenser.

The mines used with theGator arethe BLU-91/B AT mine and the BLU-92/B
AP mine. They are similar to the mines used with the Volcano system. The
mines are capable of three field-selectable SD times (4 hours, 48 hours, and 15
days). Both types of mines are encased in a plastic, square-shaped protective

3-14 Scatterable Mines and Mine Delivery Systems

FM 20-32

E mployment

Figure 3-4. Gator SCATMINE system

casing that is designed to aid dispersion and lessen ground impact upon
delivery.

The mines are contained inside tactical munition dispensers (TM Ds) that are
attached under the wings of high-performance, fixed-wing aircraft. TheTMD
is a USAF dispenser that was designed for common use with cluster
munitions. The Gator is compatible with the USAF A-10, F-4, F-15, F-16, B-l,
and B-52 aircraft and with theUSN A-6, A-7, F-4, FA-18, and AV-8B aircraft.

TheTMD is released in the air and allowed to fall free. Four linear charges
along the edge of theTMD cut the outer casing, and the mines are
aerodynamical ly dispersed. The maximum delivery speed is 800 knots at
altitudes of 75 to 1,500 meters. The area of minefield coverage depends on the
number of munitions carried, the aircraft speed and altitude, and the altitude
where the fuse functions and opens the dispenser. The average area covered is
approximately 200 by 650 meters.

Gator missions are primarily used at long range to disrupt, fix, turn, or block
enemy troop movement beyond the fire-support coordination line (FSCL). For
use in interdiction missions beyond the FSCL, submit requests for Gator
missions as early as possible to nominate targets for the theater air-tasking
order. Gator munitions are well-suited for placing minefields on specific
concentrations of forces (artillery, logistic, and C 2 ) that are out of range of
conventional artillery.

Scatterable Mines and Mine Delivery Systems 3-15

FM 20-32

E mplacement

While the Gator can provide close combat support, deep-interdiction mining is
expected to be its primary mission. Gator minefields are normally employed in
conjunction with other deep indirect -fire attacks, such as area of interest (Al ),
battlefield air interdiction (BAI), or joint air-attack team (J AAT). However, a
Gator minefield may be employed in conjunction with close air support (CAS)
and covered by close indirect- and direct-fire systems. Typical mining missions
include—

Isolating objectives.

Countering ADA/arti I lery fires.

Denying terrain.

Disrupting and disorganizing support activities.

Inflicting personnel and equipment losses.

The extended range of the Gator system, together with its speed and
responsiveness, makes it one of the most influential weapon systems on the
deep battlefield. The primary limitations of the Gator are the availability of
high-performance aircraft to emplace the mines and the system's relative
ineffectiveness on units in column. During any conflict, aircraft will be in high
demand and will not always be immediately available for a Gator mission
when required. Communications may also pose a problem because mission
execution is a joint US Army-USAF operation.

The Gator is well suited to support contingency operations and amphibious
landing operations in an immature theater when there is no danger to
friendly forces or host-nation assets. Gator minefields are one of the light-
force commander's few durable, long-range antiarmor weapons.

As an aircraft-delivered munition, the Gator is a corps asset. The Gator is a
BAI mission and is controlled by the tactical air control center (TACC).
Missions should be requested as early as possible (no later than 36 hours in
advance) through fire-support channels to the corps FSE. As a mine system,
Gator missions must be approved by corps. The corps FSE passes the mission
to the theater or army air headquarters to be included on the theater air-
tasking order for execution. I n support of BAI or CAS, Gator sorties may be
allocated down to battalion level, with final control exercised by the battalion
ALO. I mmediate Gator missions can also be requested directly from the
maneuver unit's TACC. The same records and reports applicable to other
SCATMINE systems are used with theGator mine system. Close cooperation
and coordination among the G3/S3, the staff engineer, and the ALO are
required for planning and executing Gator missions.

As with artillery-delivered minefields, the engineer is primarily responsible
for identifying the minefield location, size, duration, and density. Minefield
density is varied by changing the orientation of the minefield with respect to
the target AA. Figure 3-5 illustrates how minefield orientation is changed to
achieve a fix or block effect. Normally, Gator is employed as a fix obstacle with
a front of 650 meters. Emplacing a fix-obstacle group along a battalion AA
(1,500 meters) requires twoGator sorties, each delivering one minefield. Each
Gator minefield would have a front of 650 meters and a depth of 200 meters.

3-16 Scatterable Mines and Mine Delivery Systems

C2, FM 20-32

The minefields would be delivered at different locations so that the group
covers the entire AA and affects the entire enemy battalion.

Six Gator dispensers (72 AT and 22 AP mines each)
NOTE: Add 275 m to all dimensions for the safety zone.

-+ 650 m ►

200 m

^mMmmmeMMmMMM(m :

AA2

BLOCK

AA1

FIX

Volcano

Figure 3-5. Gator minefield

The Volcano multiple-delivery mine system (Figure 3-6, page 3-18) can be
dispensed from the air or on the ground. It can be mounted on any 5-ton truck,
an M548 tracked cargo carrier, a heavy expanded mobility tactical truck
(HEMTT), a palletized load system (PLS)flat rack, or a UH-60A Blackhawk
helicopter. The Volcano uses modified Gator mines and consists of four
components (Figure 3-7, page 3-18)— the mine canister, the dispenser, the
dispenser control unit (DCU), and the mounting hardware (aircraft also
require a jettison kit). The Volcano uses M87 and M87A1 mine canisters. The
M87 mine canister is prepackaged with five AT mines, oneAP mine, and a
propulsion device inside a tube housing. The M87A1 mine canister is
prepackaged with six AT mines and a propulsion device. The mixture of mines
is fixed and cannot be altered. Mines are electrically connected with a web
that functions as a lateral dispersion device as the mines exit the canister.
Spring fingers mounted on each mine prevent it from coming to rest on its
edge. All canisters are capable of dispensing mines with 4-hour, 48-hour, and
15-day SD times. TheSD times are field-selectable prior to dispensing and do
not require a change or modification to the mine canister. The arming time is
2 minutes 15 seconds for AT and AP mines. The reload time (not including
movement time to the reload site) for an experienced four-man crew is
approximately 20 minutes.

Scatterable Mines and Mine Delivery Systems 3-17

C2, FM 20-32

Figure 3-6. Volcano mine system

Vehicle mounting hardware

Aircraft mounting hardware

M87-series
mine canister

j —

ii

•

■ 1

- 1

<£

T

O'i

;d

X=

TT

M 139 dispenser

DCU

Figure 3-7. Volcano components

3-18 Scatterable Mines and Mine Delivery Systems

C2, FM 20-32

E mployment

The dispenser consists of an electronic DCU and four launcher racks. Four
racks can be mounted on a vehicle, and each rack can hold 40 M87-series mine
canisters. The racks provide the structural strength and the mechanical
support required for launch and provide the electrical interface between the
mine canisters and the DCU. Mounting hardware secures the racks to the
vehicle or the aircraft. Mounting hardware for the Blackhawk includes a
jettison subassembly to propel the Volcano racks and canisters away from the
aircraft in the event of an emergency.

The operator uses the DCU to control the dispensing operation electrically
from within the carrier vehicle. The DCU provides controls for the arming
sequence and the delivery speed and sets mineSD times. The DCU allows the
operator to start and stop mine dispensing at anytime. A counter on the DCU
indicates the number of remaining loaded canisters on each side of the carrier.

Mines are dispensed from their canisters by an explosive propelling charge.
For ground vehicles, the mines are dispensed 25 to 60 meters from the vehicle
at ground speeds of 8 to 90 kph. The average time to emplace one ground
Volcano load (160 canisters) is 10 minutes.

The primary mission of the Volcano is to provide US forces with the capability
to emplace large minefields rapidly under varied conditions. The Volcano can
be rapidly attached to air or ground vehicles. It is used to emplace tactical
minefields; reinforce existing obstacles; close lanes, gaps, and defiles; protect
flanks; and deny probable enemy air-defense sites. Volcano minefields are
ideal for providing flank protection of advancing forces and for operating in
concert with air and ground cavalry units on flank guard or screen missions.

The air Volcano is the fastest method for emplacing large tactical minefields.
When employed by combat aviation elements in support of maneuver units,
close coordination between aviation and ground units assures that Volcano-
dispensed mines are emplaced accurately and quickly. Although mine
placement is not as precise as it is with ground systems, air Volcano
minefields can be placed accurately enough to avoid the danger inherent in
minefields delivered by artillery or jet aircraft. Air Volcano minefields can be
emplaced in friendly and enemy territory. They should not be planned in areas
of enemy observation and fire because the helicopter is extremely vulnerable
while flying at the steady altitude, the speed, and the path required to
emplace the minefield. The air Volcano is the best form of an obstacle reserve
because a minefield can be emplaced in minutes.

The ground Volcano is designed to emplace large minefields in depth. It is
normally employed by combat engineer units. These mounted dispensers are
primarily used to emplace tactical minefields oriented on enemy forces in
support of maneuver operations and friendly AT fires. The system is
vulnerable to direct and indirect fires, so it must be protected when close to
the F LOT. It is ideal for use as an obstacle reserve, employed when the enemy
reaches a decision point that indicates future movement. Obstacles can then
be emplaced in depth on the avenues the enemy is using, leaving other
avenues open for friendly movement.

Scatterable Mines and Mine Delivery Systems 3-19

C2, FM 20-32

E mplacement

The principles and procedures of Volcano emplacement are significantly
different for air- and ground-delivery systems. This section outlines the use of
the ground Volcano system to empl ace disrupt, fix, turn, and block minefields.
The air Volcano system is discussed in detail in Appendix D. Both air and
ground Volcano systems are capable of emplacing nonstandard minefields.
However, the emplacement norms below streamline identifying resource
requirements and conducting emplacement drills.

Air and ground Volcano systems emplace a minefield with an average AT
linear density of 0.72 mine per meter and an AP linear density of 0.14 mine
per meter. These densities may vary slightly since some mines will fail the
arming sequence and self-destruct 2 to 4 minutes after dispensing.
Additionally, some mines may not orient correctly, will not deliver their full
mine effect, and will not produce a K-Kill. The probability of failing the
arming sequence and misorienting is relatively small and does not
appreciably degrade the minefield's lethality. For tracked vehicles, the AT
density yields more than 80 percent probability of encounter. Volcano AT
mines do not have AH Ds but are highly sensitive to any movement once they
are armed. Any attempt to remove the mines will likely result in detonation.

The basic site layout is extremely important, and it is the same for air and
ground Volcano minefields. The limits of Volcano minefields are marked before
emplacement when the situation (planned targets within the main battle area
[MBA] of a defensive operation) allows it. The minefield is not premarked
when the situation (offensive operations or situational obstacles) does not
allow it. If the mines have not self-destructed, the minefield is marked before
the unit leaves the area or turns it over to an adjacent unit. M inefield
marking must include the safety zone, which is 40 meters from the start and
end points and 80 meters to the left and right of thecenterline. The start and
end points of the strip centerline are marked based on the minefield front and
the number of strips. For a ground Volcano minefield, guide markers are
emplaced along the path of the centerline but are offset left to allow the host
vehicle to remain on thecenterline. When using a ground-delivery system,
minefield marking must leavea gap along each centerlinefor vehicle entrance
and exit. The number of guide markers used depends on the terrain and the
visibility. Guide markers are not required for an air Volcano minefield because
the pilot will use the start and end points of the centerline as reference poi nts.

Figure 3-8 illustrates the emplacement pattern for standard disrupt and fix
minefields using the ground or air Volcano. Disrupt and fix minefields use
only one centerline to give a minefield depth of 120 meters (ground) or 140
meters (air), not including the safety zone. The strip centerline is 277 meters
(ground) or 278 meters (air) long. The host vehicle moves toward the start
point, achieving and maintaining theground or air speed selected on theDCU.
The operator depresses the launch switch on theDCU when the vehicle passes
the start marker, and he stops dispensing mines when the vehicle passes the
end marker. The operator dispenses 40 canisters (20 on each side) along the
centerline. One full load of ground or air Volcano empl aces four disrupt or fix
minefields. For ground emplacement, the vehicle moves out of the minefield,
marks the exit, and waits a minimum of 4 minutes before approaching the
minefield. This delay allows faulty mines to self-destruct.

3-20 Scatterable Mines and Mine Delivery Systems

C2, FM 20-32

20 m

5-ton

• - "

120 m (ground)
140 m (air)

277 m (ground)

278 m (air)

Start or end marker
f" Guide marker

Figure 3-8. Volcano disrupt and fix minefields

Turn and block minefields (Figure 3-9, page 3-22) areemplaced using the
same basic procedures as those used for disrupt and fix minefields. However,
turn and block minefields use two strip centerlines along a front of 555 meters
(ground) or 557 meters (air). During site layout, centerlines are separated by
at least 320 meters for both ground and air delivery. This gives a total
minefield depth of 440 meters (ground) or 460 meters (air). The operator
dispenses 80 canisters along each centerline (40 on each side); therefore, turn
and block minefields require a total Volcano load of 160 canisters. One full
load of ground or air Volcano emplaces one turn or block minefield. Wherever
possible, two ground Volcanoes are employed simultaneously on turn and
block minefields. When only one ground delivery system is used, the crew
must wait 4 minutes after dispensing the first strip before dispensing the
second strip. This allows mines that fail the arming sequence to self-destruct.
For air delivery, two sorties are also optimal; but demands for sorties
elsewhere in the division may preclude the simultaneous employment of two
Blackhawks.

Modular Pack Mine System

The MOP MS (Figure 3-10, page 3-22) is a man-portable, 162-pound, box-
shaped mine dispenser that can be emplaced anytime before dispensing
mines. The dispenser contains 21 mines (17 AT and 4 AP). The mines have
leaf springs along their outer circumference that are designed to push the
mines into proper orientation if they land on their side.

Each dispenser contains seven tubes; three mines are located in each tube.
When dispensed, an explosive propelling charge at the bottom of each tube
expels mines through the container roof. Mines are propelled 35 meters from
the container in a 180-degree semicircle (Figure 3-11, page 3-23). The
resulting density is 0.01 mine per square meter. The safety zone around one
container is 55 meters to the front and sides and 20 meters to the rear.

Scatterable Mines and Mine Delivery Systems 3-21

C2, FM 20-32

" A

120 m

50 m

•••••••••••••• ."J" * • Ii35 m

gt _r_ i r rj

Y20m

• *

440 m
(ground)

460 m
(air)

20 m

• •••••••••••• * * •

320 m (minimum)

5 ton

r

r» 5 ton ■*-
. c .-■:"""■ J_

20 m

20 m

555 m (ground), 557 m (air)

Start or end marker
X* Guide marker

tr

Figure 3-9. Volcano turn and block minefields

<*

iffiii

I*.. -J..

i. ' i \i

>

< t »>

Figure 3-10. MOPMS

3-22 Scatterable Mines and Mine Delivery Systems

C2, FM 20-32

Safety
zone

Figure 3-11 . MOPMS emplacement and safety zone

Mines are dispensed on command using an M71 remote-control unit (RCU) or
an electronic initiating device. Once mines are dispensed, they cannot be
recovered or reused. If mines are not dispensed, the container may be
disarmed and recovered for later use.

The RCU can recycle the 4-hour SD time of the mines three times, for a total
duration of approximately 13 hours. Mines with a 4-hour SD time will begin to
self-destruct at 3 hours and 12 minutes. All active mines must be recycled
within 3 hours of the initial launch or last recycle. This feature makes it
possible to keep the minefield emplaced for longer periods if necessary. The
RCU can also self-destruct mines on command, allowing a unit to
counterattack or withdraw through the minefield, as necessary, rather than
waiting until theSD time has expired. The RCU can control up to 15 MOPMS
containers or groups of MOPMS containers from a distance of 300 to 1,000
meters via separate pulse-coded frequencies. Coded frequencies defeat threat
electronic counter measures directed against the system.

If the M71 RCU is unavailable, a direct wire link is used in conjunction with
an M32, M34, or M57 blasting machine. By using the M32 10-cap blasting
machine, one MOPMS dispenser can be detonated at a maximum range of
1,000 meters. The M 34 50-cap blasting machine can detonate one MOPMS at
a maximum range of 3,000 meters. (Due to internal resistance, the maximum
range is decreased by 400 meters for each additional MOPMS connected in
series.) The M57 claymore-type FD can fire only one MOPMS at a maximum

Scatterable Mines and Mine Delivery Systems 3-23

C2, FM 20-32

range of 100 meters. When controlled by direct wire, MOPMS dispensers
cannot be command-detonated, and theSD time cannot be recycled.

E mployment

E mplacement

WARNING
The MOPMS dispenser has seven launch tubes. If all seven tubes are not
visible after deployment, mines are jammed in the tube(s). In this event,
clear the area and notify EOD. The dispenser is considered to be UXO; do
not attempt to recover the dispenser.

The MOPMS provides a self-contained, on-call minefield emplacement
capability for all forces. It can be command-detonated, reused (if mines are not
dispensed), and directly emplaced to provide complete and certain coverage of
small or critical targets. The ability to command-detonate mines or extend
their SD time provides an added flexibility not currently available with other
SCATMINE systems. With its unique characteristics, the MOPMS is ideally
suited for thefollowing minefield missions:

• Emplacing hasty protective minefields.

• Emplacing deliberate protective minefields (cases emplaced, but
mines not dispensed).

• Emplacing nuisance minefields (trails, crossing sites, landing zones
[LZs], drop zones [DZs], and road junctions).

• Emplacing tactical disrupt and fix minefields.

• Closing gaps and lanes in existing minefields.

• Temporarily closing counterattack routes.

• Supporting ambushes.

• Supporting military operations in built-up areas (MOBA) operations.

When the MOPMS is used to close lanes, the container is positioned and
dispensed by personnel in an overwatch position from a safe standoff. The
MOPMS is ideally suited for creating a small disrupt obstacle in support of
engineers executing a reserved demolition target. Engineers prepare the
reserved target for demolition and empl ace several MOPMS units on the
enemy side, just out of target range. When the last forward element passes
through the target, the firing party detonates the charges. If something goes
wrong or the firing party needs more time, MOPMS mines can be dispensed to
disrupt the enemy before it reaches the target.

The MOPMS provides light and special forces with a versatile, compact
system for emplacing nuisance minefields. It can be used in low-, mid-, and
high-intensity conflicts and in a variety of environments. The MOPMS cannot
be transported long distances by hand because of its weight, so its use is
limited.

MOPMS dispensers are issued as standard Class V munitions and are drawn
from an ASP on a mission-by-mission basis. RCUs are organizational issues of
equipment and are assigned to engineer and combat arms units. Due to the

3-24 Scatterable Mines and Mine Delivery Systems

C2, FM 20-32

weight of the system, it will normally be transported by vehicle, as close as
possible to the emplacement site, where it can easily be hand-emplaced by
four soldiers using the four foldout carrying handles.

To ensure that the minefield will be dispensed in the proper location, the
container should be carefully sited by the noncommissioned officer in charge
(NCOIC). Several containers can be used together to provide a greater area of
coverage or a higher mine density. If mines are not dispensed immediately,
containers should be camouflaged and, if possible, buried. When placed in
sand or snow, brace the containers to prevent them from moving during mine
dispensing. Designate a firing point that gives the operator clear observation
of the area to be mined. Firing systems must be inspected according to
MOPMS operating instructions. If mines aredispensed immediately, remove
empty containers to avoid revealing the minefield location.

The MOPMS can be employed to emplace disrupt and fix tactical minefields.
Emplacement procedures are the same as for protective minefields above.
However, MOPMS containers are arranged in a specific pattern to achieve the
necessary depth, front, and density. Once the minefield is marked (to include
the safety zone), MOPMS containers are arranged as shown in Figure 3-12 for
a disrupt minefield. The safety zone is 55 meters from the front and sides and
20 meters from the rear of the container. The disrupt minefield uses four
MOPMS containers that are spaced 70 meters apart to give a minefield front
of 280 meters. Other MOPMS containers are offset from the baseline by 35
meters to give the minefield a depth of 70 meters. All containers are fired
using the same RCU or FD.

280 m

70 m

70 m

70 m

70 m

70 m

° AP mine
• AT mine

Four MOPMSs required

Figure 3-12. MOPMS in a disrupt minefield

Scatterable Mines and Mine Delivery Systems 3-25

C2, FM 20-32

Figure 3-13 illustrates the arrangement of MOPM S containers for a fix
minefield. The basic layout is the same as the disrupt minefield; however, the
fix minefield has one additional MOPMS that is placed 70 meters forward of
the baseline to act as an I OE. This gives the same 280-meter minefield front
but increases the minefield depth to 115 meters.

70 m

MOPMSs placement along
the horizontal plane is
variable, like an IOE.

35 m

70 m

70 m

70 m

70 m

280 m

o AP mine
AT mine

Five MOPMSs required

MARKING

Figure 3-13. MOPMS in a fix minefield

MOPMS can be used to construct turn and block tactical minefields using the
principles outlined in Chapter 2; however, turn and block minefields require
more containers than are normally availabletoa unit.

The maneuver unit that is responsible for the area of ground in which the
minefield is emplaced is also responsible for marking the minefield. This
normally requires direct coordination between elements of the maneuver
command (usually the engineer) and thedelivering/emplacing unit. However,
it is unrealistic to expect units to mark artillery-delivered ADAM and RAAM,
air-delivered Volcano, or Gator minefields. For this reason, units operating in
the vicinity of these minefields must know calculated safety zones and use
extreme caution. Scatterable minefields are marked to protect friendly troops
as shown in Table 3-7. Ground Volcano minefields are marked accordi ng to the
guidelines below.

Table 3-7. Marking scatterable minefields

Minefield Location

Marking

Enemy forward area

Unmarked

Friendly forward area

Sides and rear marked

Friendly rear area

All sides marked

3-26 Scatterable Mines and Mine Delivery Systems

C2, FM 20-32

Safety Zones

A safety zone is an area where a stray or outlying mine has a chance of
landing and laying to rest. The commander must prevent friendly forces from
maneuvering into the safety zone during the minefield's life cycle. Depending
on its specific location on the battlefield, the safety zone may be marked with
a fence.

The safety zone around a Volcano minefield is shown in Figure 3-14.

630 m

1 ,620 m

-J

Marking fence

80 m

:<■

80 m

"X"

-x-

-X-

35

m

1,110m

-X-

20

rrK

;:25m

.40 m

X Sto p dispensing

35

m

Start dispensing )(

X

^e

-x-

|20m
-X- 4 X-

-x-

1,150m

160 m

Fragment hazard zone

Figure 3-14. Ground Volcano minefield

Fragment Hazard Zones

I f an AT mine that is oriented on its side self-destructs, the E F P can
theoretically travel 640 meters. This is the maximum fragment hazard zone;
however, the chances of being struck are negligible at this distance. Tests
indicate that the acceptable risk distance is 235 meters from the outer edges
of the minefield's safety zone. This fragment hazard zone is also associated
with the Gator and MOPMS AT mines. When the MOPMS is used for
protective minefield missions, commanders must be made aware of the
fragment hazard zone.

Scatterable Mines and Mine Delivery Systems 3-27

C2, FM 20-32

Use Table 3-8 to determine safety zones and fragment hazard zones.

Table 3-8. Safety and fragment hazard zones

System

Safety Zone

Fragment Hazard Zone

ADAM/RAAM

500 to 1 ,500 meters from aim
point(s) (depends on delivery
factors)

235 meters from the outside
dimensions of the safety zone

Gator

925 x 475 meters from aim
point(s)

1 ,395 x 945 meters from aim
point(s)

Ground Volcano

1,150 x 160 meters

235 meters from start and stop
points and the centerline

Air Volcano

1,315x200 meters

235 meters from start and stop
points and the centerline

MOPMS

See page 3-28 for specific
placement.

235 meters from the outside
dimensions of the safety zone

Fencing

Fencing for ground Volcano minefields (Figure 3-14, page 3-27) is emplaced 80
meters beyond the centerline of the minefield and 40 meters from the start
and stop points. Fencing should be no closer than 20 meters from the nearest
mine.

Air Volcano minefields are not normally marked by fencing. However, if air
Volcano minefields are emplaced in friendly areas, they are marked with
fencing to protect friendly personnel. Fencing is installed before delivering an
air Volcano, and it is located 100 meters from the centerline of the minefield
and 100 meters from the start and end points. Appendix D contains detailed
information pertaining to air Volcano minefields.

3-28 Scatterable Mines and Mine Delivery Systems

C2

Chapter 4

Special-Purpose Munitions

Special-purpose munitions are hand-emplaced and used to create an
expedient obstacle, enhance existing ones, and attack specific types of
targets. The commander can employ these munitions to support his
scheme of maneuver, to mass firepower, and to disrupt or destroy enemy
forces in depth. Special considerations must be made in the planning
process to effectively employ special -purpose munitions.

Special-Purpose Munitions 4-1

FM 20-32

M18A1 CLAYMORE

The M18A1 claymore munition (Figure 4-2) is a fragmentation munition that
contains 700 steel balls and 682 grams of composition C4 explosive. It weighs
1.6 kilograms and can be detonated by command (Korea Only: or trip wire).
It is activated by electric or nonelectric blasting caps that are inserted into the
detonator well. The claymore projects a fan-shaped pattern of steel balls in a
60-degree horizontal arc, at a maximum height of 2 meters, and covers a
casualty radius of 100 meters. The forward danger radius for friendly forces is
250 meters. The backblast area is unsafe in unprotected areas 16 meters to
the rear and sides of the munition. Friendly personnel within 100 meters to
the rear and sides of the munition should be in a covered position to be safe
from secondary missiles. If the M18A1 is employed in a minefield for 72 hours
or more, the minefield must be fenced on all sides.

Detonator well

Molded, slit-type
peep sight

Scissor-type,
folding legs ~

Plastic matrix
containing steel balls

Figure 4-2. M18A1 claymore

When employing the M 18A1 claymore with other munitions or mines,
separate the munitions by the following minimum distances:

• 50 meters i n front of or behi nd other M 18Als.

• 3 meters between M 18Als that are placed side by side.

• 10 meters from AT or fragmentation AP munitions.

• 2 meters from blast AP munitions.

4-2 Special-Purpose Munitions

C2, FM 20-32

SELECTABLE LIGHTWEIGHT ATTACK MUNITION

The selectable lightweight attack munition (SLAM ) (F igure 4-3) is a
multipurpose munition with an antitamper feature. The SLAM is compact
and weighs only 1 kilogram, so it is easily portable. The SLAM is intended for
use against APCs, parked aircraft, wheeled or tracked vehicles, stationary
targets (such as electrical transformers), small fuel-storage tanks (less than
10,000-gallon), and ammunition storage facilities. The EFP warhead can
penetrate 40 millimeters of homogeneous steel.

Figure 4-3. SLAM

The SLAM has two models— one is self-neutralizing (M2) and the other is self-
destructing (M4):

• The M2 is solid green and has no labels, brands, or other
distinguishing marks. This device is used by SOF and is not available
toother units.

• The M4 is green with a black warhead (EFP) face. This device is
normally used by units designated as light, airborne, air assault, crisis
response, and rapid deployment.

See Appendix B for a description of major SLAM components.

Operating Modes

Bottom Attack

The SLAM has four possible employment methods— bottom attack, side
attack, timed demolition, and command detonation.

The SLAM has a built-in magnetic sensor, so it can be used as a magnetic-
influenced munition against trucks and light armored vehicles (Figure4-4, page
4-4). It can be concealed along trails and roads where target vehicles operate

Special-Purpose Munitions 4-3

FM 20-32

Side Attack

and can be camouflaged with dry leaves, grass, and so forth without affecting
EFP performance. Mud, gravel, water, and other debris that fill the EFP cup
have minimal impact on EFP formation and effectiveness as long as the debris
does not extend beyond the depth of the EFP cup. The magnetic sensor is
designed to trigger detonation when it senses a vehicle's overpass. For the
EFP to form properly, it needs a minimum of 13 centimeters from the point of
emplacement to the target. The bottom-attack mode is active when the
selector switch is set to 4, 10, or 24 HOURS and the passive infrared sensor
(PI RS) cover is in place. The SLAM will self-destruct (M4) or self-neutralize
(M2) if the selected time expires before the SLAM is detonated by a vehicle.

Figure 4-4. SLAM in bottom-attack mode

The SLAM is equipped with a PI RS that was specifically developed for the
side-attack mode (Figure 4-5). The PI RS detects trucks and light armored
vehicles by sensing the change in background temperature when vehicles
cross in front of the PIRS port. The PIRS is directional and aligned with the
EFP when the device is aimed. The side-attack mode is active when the SLAM
selector switch is set to 4, 10, or 24 HOURS and the PI RS cover is removed to
expose the PIRS. The SLAM will self-destruct (M4) or self-neutralize (M2) if
the selected time expires before it is detonated by a vehicle.

Timed Demolition

The SLAM's built-in timer will trigger detonation at the end of a selected time
(Figure 4-6). The timed-demolition mode is active when the SLAM selector
switch is set to 15, 30, 45, or 60 MINUTES. I n this mode, the magnetic sensor
and the PIRS are inoperable, and the SLAM will detonate after the selected
time has expired.

Command Detonation

This mode provides manual warhead initiation using standard military
blasting caps and a priming adapter (Figure 4-7). The command-detonation
capability bypasses the SLAM's fuse and safing and arming (S&A) assembly.

4-4 Special-Purpose Munitions

FM 20-32

Figure 4-5. SLAM in side-attack mode

Figure 4-6. SLAM in timed-demolition mode

Figure 4-7. SLAM in command-detonation mode

Special-Purpose Munitions 4-5

FM 20-32

Antitamper Feature

The SLAM has an antitamper feature that is only active in the bottom- and
side-attack modes. The SLAM will detonate when an attempt is made to
change the selector switch's position after arming.

M93 HORNET

The M93 Hornet (Figure 4-8) is an AT/anti vehicular off-route munition made
of lightweight material (35 pounds) that one person can carry and employ. The
Hornet is a nonrecoverable munition that is capable of destroying vehicles by
using sound and motion detection methods. It will automatically search,
detect, recognize, and engage moving targets by using top attack at a standoff
distance up to 100 meters from the munition. It is employed by combat
engineers, rangers, and SOF.

Figure 4-8. M93 Hornet

The RCU is a hand-held encoding unit that interfaces with the Hornet when
the remote mode is selected at the time of employment. After encoding, the
RCU can be used to arm the Hornet, reset its SD times, or destroy it. The
maximum operating distance for the RCU is 2 kilometers.

High winds, heavy rain, snow, ice, extreme cold, and extreme heat reduce the
Hornet's ability to detect targets at maximum range. Radio-frequency (RF)
jamming devices (such as the hand-emplaced, expandable jammer
[HEXJ AM]), limit the Hornet's communication capabilities if they are placed
in the munition field, but they will not affect the Hornet's ability to engage
targets and will not damage the system. RF jamming devices affect the remote
arming of current Hornet systems using the MOPMS RCU, and they will

4-6 Special-Purpose Munitions

C2, FM 20-32

affect future Hornet's two-way communications capability with the Centurion
remote control device.

See Appendix B for a description of Hornet components.

Employment Considerations

The Hornet's active battery pack is inserted during prearming and has an
estimated life of 4 hours. The active battery pack powers the munition from
the time it is inserted until the end of the safe-separation time, when the
built-in reserve battery is activated. To prevent munitions from becoming
duds, do not prearm them too early. Allow adequate time for travelling to the
obstacle site, emplacing mines, throwing arming switches, and expiration of
safe-separation times.

Once the Hornet is armed and the self-test is performed, the munition will
remain active until its SD time expires or until it is encountered. TheSD time
(4 hours, 48 hours, 5 days, 15 days, or 30 days) is determined by the mission
and the commander's intent. The munition will self-detonate after the SD
time has expired.

Hornet munitions have an employed life of 60 days in the prearmed mode
(remote arming) and 30 days in the armed mode. If the temperature exceeds
lOOSF, the employed life drops to 15 days in the prearmed mode and 30 days in
the armed mode.

Employment Roles

Combat engineers or maneuver forces under engineer supervision emplace
Hornets in close operations; SOF or rangers emplace Hornets in deep
operations. Hornets will be employed throughout the entire depth of the battle
space to support Army operations.

Close Operations

I n close operations, the H ornet can be—

• U sed to fix the enemy and weaken it along its AA.

E mplaced as an offensive-support weapon system because of its quick
emplacement time and wide attack area.

• Employed rapidly along exposed flanks during a maneuver as a
situational obstacle to disrupt the enemy's counterattacks.

Special-Purpose Munitions 4-7

FM 20-32

Used as a stand-alone tactical obstacle or as a reinforcement to
conventional obstacles.

Used to disrupt and delay the enemy, allowing long-range weapons to
engage more effectively.

Deep Operations

I n deep operations, the Hornet can be

Emplaced along key routes in gauntlet obstacles to disrupt and delay
threat second-echelon forces, resupply operations, and key lines of
communication (LOC).

U sed at C 2 and logistics sites to disrupt enemy operations.

Rear Operations

I n rear operations, the Hornet can be emplaced (unarmed) along key routes in
preparation for possible retrograde operations.

Early-Entry Operations

I n early-entry operations, the Hornet can be—

• Used as an additional antiarmor weapon to supplement light forces.

• Used along high speed AAs in gauntlet obstacles to buy time and
space.

Tactical Emplacement

There are four basic emplacement scenarios for the Hornet.

Conventional Minefield Reinforcement

The Hornet can be used to reinforce a conventional turn, block, or fix
minefield (Figure4-9).

Platoon engineers emplace the conventional minefield first, and then they
traverse the safe lane that is perpendicular to the minefield. The Hornets are
employed in two staggered rows, spaced 100 meters apart, 50 to 100 meters
from the front edge (on the enemy side) of the conventional minefield. It is also
recommended that a row of Hornets be placed 50 meters behind the minefield
to reduce the enemy's breaching capability. (This row will be emplaced after
the safe lane is closed.) The emplacing vehicles work toward the safe lane.

Two squads employ Hornets in two rows of ten each. One or more soldiers
provide security. U nder the supervision of a noncommissioned officer (NCO),
four soldiers in each squad vehicle start prearming the Hornets, if necessary.
They—

• Rotate the handle.

• R emove the cover.

• Insert the active battery pack and verify functionality via a solid
status light.

• Reinstall the active battery-pack cover.

4-8 Special-Purpose Munitions

FM 20-32

Enemy movement

100 m

\

Squad
no 1

wwwwwwwww

w

Squad
no 2

wwwwwwwww ysoto

1 00 m

MOPMS

CD

C

ro

CD

H

CO

Conventional
minefield

Figure 4-9. Hornet reinforcing a conventional minefield

• Select the SD time.

• Encode the Hornet with the M71 RCU and verify functionality via a
flashing status light.

• Reinstall the cover.

Each emplacement vehicle moves to the first Hornet emplacement site in each
row. Theemplacing soldier and the arming soldier dismount. Theemplacing
soldier is handed a Hornet from the vehicle. He emplaces the Hornet at the
designated site and returns to the vehicle.

The arming soldier rotates the handle on the Hornet, removes the cover and
the safety and handling (S&H) band, rotates the SD switch toU, and pushes
the arm switch to ARM . He then returns to the vehicle, taking the cover and
the S&H band with him. The vehicle travels to the next Hornet emplacement
site.

After all the Hornets in the two leading rows have been emplaced and armed,
theemplacing vehicles exit through the safe lane and usually secure it with a
MOPMS. The emplacement vehicles must beat least 475 meters (safe standoff
distance) from the nearest Hornet within 30 minutes. Before sending a remote
arming signal, vehicles must wait at least 36 minutes after the arming switch
is thrown on the last Hornet emplaced. If a rear row is required, it is emplaced
at this time. The Hornets are then remotely armed with the M71 RCU, when
required. They are now capable of covering the minefield by fire and engaging
threat tracked vehicles.

Special-Purpose Munitions 4-9

FM 20-32

Scatter able Minefield Reinforcement

The Hornet can be used to reinforce a Volcano or MOPMS turn, block, or fix
minefield (Figure 4-10). Hornet munitions are emplaced, using the same
procedures as above, before the Volcano or MOPMS minefield is emplaced.

|100

m I

Enemy movement

w w w w

W

w

Squad
no 1

^ w w w

w

w w w w

W

w

Squad
no 2

m w w

w '

'50 to
100 m

]35m

Volcano mine strip

i
'

50 m

r

35 m

Volcano mine strip

Figure 4-10. Hornet reinforcing a Volcano minefield

To ensure that the Volcano dispensing vehicle has sufficient time to reach the
safe standoff distance (475 meters), Volcano dispensing should start no later
than 30 minutes (minus the Volcano dispensing time) after the first Hornet is
armed. This allows Hornet emplacing squads to be finished or nearly finished
before the Volcano dispenser begins emplacing the minefield.

Area-Disruption Obstacle

When the X-pattern is employed, the Hornet is very effective as a disrupting
obstacle (Figure 4-11). An area-disruption obstacle is employed to disrupt the
enemy's approach prior to the start of the direct-fire battle. It causes
disruption and attrition of the advancing threat force and encourages follow-
on forces to seek an alternate route. Therefore, multiple area-disruption
obstacles will typically be employed to adequately cover the cross-country AA.
This requires coordinated action among multiple squads.

An engineer platoon emplaces a Hornet area-disruption obstacle. The obstacle
typically consists of 20 Hornets (five clusters of four Hornets each) employed
in an X-pattern over a 1- by 1-kilometer area. Individual Hornets are
emplaced 100 meters apart. E mplacing this obstacle must be done as a
dispense-and-roll operation to ensure that the emplacing vehicles can reach
the safe standoff distance (475 meters) from any armed H ornets.

4-10 Special-Purpose Munitions

C2, FM 20-32

Squad no 1

Enemy movement
1

Squad no 2

5n

T

JPW

Jp w

^^

Sw w\

^W

pfvt
w

/ w

3n*

~ NOTE:

Arrows indicate direction of emplacement. ^^

Figure 4-11. Hornet area-disruption obstacle

Area-disruption obstacles are normally armed by remote, but they can be
manually armed under the following conditions:

• METT-TC requires rapid emplacement and arming.

• Terrain reconnaissance determines that there are no major
impediments (rough terrain, vegetation) to maneuver.

• Emplacement is done during daylight hours (mission-oriented
protective posture [MOPP] level Oonly).

Hornets are prearmed the same as above. Two squads lay the Hornets in
unison, starting with the two emplacement sites closest to the enemy. Each
squad drives in a straight line, crossing paths at the middle of the X, and
empl aces ten Hornets.

A soldier in the back of each emplacing vehicle throws the arming switch and
sets the Hornet down or drops it off (base down) the back of the vehicle. After
all the Hornet clusters are empl aced, squad vehicles quickly travel to the 475-
meter safe standoff distance (no further than 2 kilometers) to prepare for
remote arming. Hornets can be remotely armed 36 minutes after the arming
switch is thrown on the last Hornet empl aced. If manual arming is used,
Hornets automatically arm at the end of their safe-separation time (5 to 6
minutes after the arming switch is thrown).

Special-Purpose Munitions 4-11

C2, FM 20-32

Gauntlet Obstacle

Hornet gauntlet obstacles (Figure 4-12) areemplaced by an engineer platoon
and are very effective in constricted terrain along the enemy's AA and at
choke points. A Hornet gauntlet typically consists of 40 to 50 Hornets
employed in a series of clusters (Figure 4-13). Each cluster contains 3 to 6
Hornets. The Hornets in each cluster are emplaced at 50-meter intervals,
perpendicular to the road centerline, on alternating sides of the road/AA, and
25 to 50 meters (depending on the terrain and the vegetation) off the side of
the road/AA. The distance between clusters varies from 750 to 2,000 meters so
that the advancing threat force is kept guessing about when they will
encounter the next cluster.

Enemy movement

I

W

W

w

50 m

50 m

W

w

w

Initial emplacement
position (located up to
1 kilometers from the
mine dump)

Figure 4-12. Hornet gauntlet obstacle (one cluster)

Before laying any Hornets, the munitions are prearmed as above. Soldiers also
set the target switch to HIT for clusters closest to the enemy, so that the
Hornets will only engage heavy tracked vehicles. The intent is to make threat
forces commit to a route they perceive to be clear.

Hornets areemplaced beginning on the friendly side of the cluster. The first
engineer squad emplaces Hornet munitions beginning with the cluster closest
to the enemy. The emplacement vehicle drives even with the first Hornet

4-12 Special-Purpose Munitions

FM 20-32

Enemy movement

\

1st cluster

250 m

750 to 2,000 m

2d cluster I 250 m

750 to 2,000 m

i

3d cluster

250 m

t

750 to 2,000 m

i_

2d engr squad
begins arming

010023Sep

010023Sep

010023Sep

cc
Q.

a>
o

CD

>

ASSUMPTIONS:

1 . The gauntlet consists
of nine clusters.

2. Each squad in the
platoon employs three
clusters of three to six
Hornets.

3. All Hornets are armed
by the manual mode,
from clusters one through
nine.

Figure 4-13. Hornet gauntlet obstacle (platoon)

emplacement site. Theemplacing soldier dismounts, and a soldier in the
vehicle hands him a Hornet. The emplacing soldier then proceeds to the
Hornet emplacement site. The vehicle travels to a point even with each
subsequent emplacement site. A soldier deploys at each emplacing site to lay
one of the remaining Hornet munitions in the cluster. The vehicle then turns
around and stops even with the last Hornet (on the enemy side) in the cluster.

U pon reaching the Hornet employment location, each emplacing soldier
removes the cover and the S&H band, rotates the SD switch to U, and on the
command (audible or visual signal) of the NCOIC, pushes the arm switch to
ARM . Once the Hornets' arming switches are thrown, soldiers return to the
road, taking the covers and the S&H bands with them, and wait to be picked
up by the emplacement vehicle. After all the soldiers are in the emplacing
vehicle, the driver quickly travels to the safe standoff distance (475 meters).
The Hornet munitions in the first cluster will arm at the end of the safe-
separation time (5 to 6 minutes).

Special-Purpose Munitions 4-13

FM 20-32

The squad repeats the emplacement process for the next Hornet cluster in the
gauntlet, taking care not toemplaceany Hornets or drive within 475 meters of
the previous cluster. Each squad in the platoon typically emplaces three
clusters in the Hornet gauntlet, or 9 to 18 total Hornets.

Figure 4-14 shows Hornet emplacement in the battle space. The example used
is in support of a defensive position where Volcano mines are used as tactical
obstacles.

i 9 i
i W i

071000Z

Hornet conventional
obstacle integration

i m i
i w i

L — — — J

071030Z

Hornet

X-pattern

i W i
i W i

L — — — J

071035Z

Hornet
gauntlets

<y

i W i

L _ _ _ J

071200Z

<#

i W i

L _ _ _ J

071230Z

i • i
i W i

071130Z

5 km — .

4 km —

3 km—

2 km -

1 km-

7

Figure 4-14. Hornet-enhanced turn-and fix-obstacle groups

Deep-Battle Interdiction Weapon

SOF or ranger units emplace Hornet munitions in the deep battle area as
interdiction weapons. A typical mission requires a unit ranging in size from a
six-man team to an entire company. The number of Hornets carried by the
unit depends on the mission and the mode of insertion (vehicle, aircraft, or
dismounted troops); a man can normally carry only one Hornet. Hornets are
typically used to support a raid against an enemy position or complex and at
bridges or choke points along high-speed AAs used by advancing second-
echelon forces or for resupply I n these roles, the Hornets areemployed similar
to the clusters in a gauntlet obstacle.

4-14 Special-Purpose Munitions

C2, FM 20-32

Camouflage and Concealment

The best camouflage and concealment for the Hornet is tall grass and brush.
The Hornet can be partially buried if the terrain or the vegetation does not
provide effective natural camouflageand concealment. Placing the Hornet in a
hole degrades its performance, so it should only be done when Hornets cannot
be covered by fires or protected from tampering by dismounted enemy. The
following conditions must be met:

• The depth of the hole must not exceed 4 inches, because the acoustic
sensors must be above ground level.

• The hole must not restrict the Hornet's ability to rotate and tilt its
body and to fire the sublet. To meet this requirement, the hole must be
at least 36 inches wide and flat enough to support the munition.
Although the Hornet should be placed on a flat surface if possible, it
can operate on slopes up to 15 degrees.

Munitions placed at ground level should be no closer to obstructions than the
distances shown in Table 4-1.

Table 4-1. Hornet minimum emplacement distances

Maximum
Obstruction Height

Minimum Employment
Distance from Obstruction

1 m

3 m

2.4 m

5 m

6.5 m

15m

25 m

25 m

When the Hornet is emplaced and concealed, remove all indicators of excess
soil and camouflage material before performing the arming sequence.

Recording and Marking

When the Hornet munition field is completed, theOIC will identify an NCO to
be the recorder. The NCO will collect data from the NCOICs of theemplacing
squads and complete DA Form 1355 as outlined in Chapter 8. The 01 C will
ensure that the DA Form 1355 is completed timely and accurately.

Marking the Hornet munition field will be completed as prescribed in Chapter
2. The fence will be no closer than 150 meters from the nearest Hornet
munition. Marking must be completed before emplacing the munitions.

Special-Purpose Munitions 4-15

FM 20-32

4-16 Special-Purpose Munitions

This chapter implements STANAG 2990.

Chapter 5

Conventional Mines

Conventional mines are hand-emplaced mines that require manual
arming. This type of mine laying is labor-, resource-, and transport-
intensive Soldiers emplace conventional mines within a defined, marked
boundary and lay them individually or in clusters. They record each mine
location so that the mines can be recovered. Soldiers can surface lay or
bury conventional mines and may place AHDs on AT mines.

ANTITANK MINES

The M15, M19, and M21 AT mines are used by US forces. They are shown in
Figure 5-1, and their characteristics are listed in Table 5-1, page 5-2.

Setting knob
in S position

Safety
clip

M15

Pressure
plate

M607 fuse

Activator-well
plug

\ Safety-clip cord
Carrying-cord handle

M19

M21

M15

Figure 5-1 . AT mines

The M15 AT mine is 337 millimeters in diameter and 125 millimeters high. It
weighs 13.5 kilograms and contains 9.9 kilograms of Composition B explosive.
The primary fuse well is on the top center of the mine; secondary fuse wells
are on the side and bottom. The M15 can contain the following fuses:

Conventional Mines 5-1

FM 20-32

Table 5-1. Characteristics of AT mines

Mine

DODIC

Fuse

Warhead

AHD

Explosive
Weight

Mine
Weight

Mines per
Container

M15w/
M603 fuse

K180

Pressure

Blast

Yes

9.9 kg

13.5 kg

1

M15w/
M624 fuse

K1 80 (mine)
K068 (fuse)

Tilt rod

Blast

Yes

9.9 kg

13.5 kg

1

M19

K250

Pressure

Blast

Yes

9.45 kg

12.6 kg

4

M21

K181

Tilt rod or
pressure

SFF

Yes*

4.95 kg

7.6 kg

4

'Conventional AHDs will not couple with this mine; however, the M142 multipurpose FD can be emplaced
under this mine.

M19

M21

M 603 fuse. When the M 603 fuse is employed on the primary fuse well,
the M 15 is a track-width mine that is activated by 158 to 338
kilograms on the pressure plate. This produces an M -K ill.

M624 fuse. When the M624 fuse (with tilt rod) is employed on the
primary fuse well, the M 15 is a full-width mine that is activated by a
deflection of 20 degrees or 1.7 kilograms of pressure to the tilt rod.
Depending on the armor, this produces an M-Kill or a K-K ill.

The M 19 AT mine is a low-metallic, square-shaped mine that measures 332 by
332 millimeters and is 94 millimeters high. It weighs 12.6 kilograms and
contains 9.45 kilograms of Composition B explosive, a tetryl booster pellet,
and an M606 integral fuse. When the setting knob on the pressure plate is in
theS (safe) position, the mine cannot function by action of the main fuse.
After the safety clip has been removed and the setting knob turned to the A
(armed) position, a force of 157.5 to 225 kilograms on the pressure plate
depresses the Belleville spring and begins the firing chain. A standard FD
may be used with the M2 activator in any of the secondary fuse wells on the
sides or the bottom of the mine. When the M 19 is employed, it is difficult to
detect because of its plastic construction. It produces an M-Kill with a blast
effect.

The M21 AT mine is 230 millimeters in diameter and 206 millimeters high. It
weighs 7.6 kilograms and has 4.95 kilograms of Composition H6 explosive.
The mine is activated by 1.7 kilograms of pressure against a 61-centi meter-long
rod on the end of the M 607 fuse. It uses an M-S pi ate to produce a K-K ill. The
M21 with tilt rod must be buried or staked (use three stakes at the 12, 4, and
8 o'clock positions) so that enemy vehicles will not tip the mine over. Without
the tilt rod, the mine is activated by 130.5 kilograms of pressure on the M607
fuse and produces an M-Kill by blast effect.

5-2 Conventional Mines

C2, FM 20-32

ANTIPERSONNEL MINES

The M14 and M16 AP mines are used by US forces on the Korean
peninsula. They are also used by many other countries. The M16 AP
mine is likely to be seen in a modified form. These mines are shown in
Figure 5-2, and their characteristics are listed in Table 5-2.

Indicating ^
arrow

Fuse-

lit!?'

Carrying cord

M14

Pressure prongs

Release-pin
ring

MINE
30NNI

nn-oo noo.

l6pf|}PERSONNELMI<$$

■*>is-.

m

m

M16

M14

Figure 5-2. AP mines

Table 5-2. Characteristics of AP mines

Mine

DODIC

Fuse

Warhead

AHD

Explosive
Weight

Mine
Weight

Mines per
Container

M14

K121

Pressure

Blast

No

28.4 g

99.4 g

90

Mi-
series

K092

Pressure
or trip wire

Bounding
frag

No

450 g

3.5 kg

4

The M14 AP mine is a low-metallic blast mine consisting of a main
charge (28.4 grams of tetryl) and a plastic fuse with a steel firing pin.
It is cylindrical in shape (56 millimeters in diameter and 40
millimeters high) and weighs 99.4 grams. The pressure plate has an
indented, yellow arrow that points to the A or S position on top of the
fuse body. A force of 11.5 to 13.5 kilograms depresses the pressure
plate and causes the Belleville spring to drive the firing pin into the
detonator. The M14 is not designed to kill, but to incapacitate. The
M14 AP mine has been modified by gluing a metal washer to the
bottom of the mine. The modification was directed to improve the
detectability of the mine. Unmodified mines are not authorized for
use by US forces.

Conventional Mines 5-3

FM 20-32

M16

TheM16AP mineisa bounding fragmentation mine that consists of a
mine fuse (M605), trinitrotoluene (TNT) explosive, a propelling
charge, and a projectile that are contained in a sheet-steel case. The
mine is 103 millimeters in diameter, 199 millimeters high (including
the fuse), and weighs 3.5 kilograms. The principal difference between
the M16, M16A1, and M16A2 versions are in the construction of the
detonators and boosters. The casualty radius is 27 meters for the M16
and M16A1 and 30 meters for the M16A2. A pressure of 3.6 to 9
kilograms applied on one or more of the three prongs of the M605
fuse or a pull of 1.4 to 4.5 kilograms on the trip wire will activate the
mine.

EMPLACING MINES

The method used to lay and conceal each type of mine depends on the method
of mine operations, the type of ground in which the mine is to be laid, and the
type of ground cover availablefor camouflage.

Standard-pattern mine laying is laborious and time-consuming, but it is more
effective and flexible than row mine laying and allows better mine
concealment. Standard-pattern mine laying is well suited for protective
minefields, and it can be used in terrain where the nature of the ground
makes row mine laying impractical.

To achieve the maximum effect, mines must belaid where they cannot be seen
and where a vehicle or a person exerts enough pressure to detonate them. The
following rules should be applied to achievethe maximum effects of mines:

Mines With Prongs

Korea Only: If the mine is activated by its prongs, it should be buried
flush with the ground so that only the tips of the mechanism are
exposed (Figure 5-3). A mine buried in this manner is held firmly
upright. The target exerts a direct, downward pressure rather than a
sideways thrust. The mine is protected from damage and is difficult
to see. If it is buried more deeply, it becomes unreliable because the
layer of spoil may prevent the mine mechanism from operating.

If the mine is activated by atrip wire, it should be buried so that the trip
wire is at least 2 to 3 centimeters above the ground (Figure 5-4).

Mines With Pressure Plates

Mines with pressure plates will function when completely buried as long as
the cushion of earth above them is not too thick. AT mines are normally
buried with the top of the mine approximately 5 centimeters below ground
level.

5-4 Conventional Mines

FM 20-32

Figure 5-3. Prong-activated AP mine

Maximum 10 m

Minimum 2 to 3 cm

f 1L-

Figure 5-4. Trip-wire-activated AP mine

Conventional Mines 5-5

FM 20-32

Korea Only: AP mines are usually placed in a hole and covered with
camouflage material. If the hole is only slightly larger than the mine,
the weight of the target may be supported by the shoulder of the hole,
and the mine will fail to activate. Such bridging action can be
avoided if the hole is dug much wider than the mine (Figure 5-5).

'-it&z&m

'^//x^y ■"^;-> ~-"''-^ > y.--^,-"-^vo> Vl ''

■*!*<•<<$#&

Figure 5-5. Buried mine with pressure plate

Mines With Tilt Rods

Tilt-rod fuses normally require the body of the mine to be buried and the tilt-
rod assembly to be clear of the ground (Figure 5-6). A tilt-rod fuse is preferred
in areas where vegetation is sufficient to conceal the extension rod.
Camouflage materials are carefully used to prevent premature detonation or
interference with the normal functioning of the fuse. Extension rods are
camouflaged before the mine is armed. If tilt rod mines are surface-laid, they
must be staked.

Bearing Boards

Concealment

High pressure is required to activate AT mines. When burying a mine in soil
that has a low bearing pressure (such as soft sand or clayey soil), it may be
necessary to place a board or another bearing plate under the mine.
Otherwise, the mine may not detonate when it is forced down.

After digging the hole for a mine, place the spoil in a sandbag to reduce the
evidence of mining. If a sandbag is not available, heap the spoil. Camouflage
all traces of digging after the mine is laid. If the ground cover is turf or other
matted, root material, remove spoil that cannot be hidden. Cut the sod in an
X, I, or U shape in the area where the mine is to be placed; lay the mine; and
then roll the sod back in place to camouflage the mine. Loose earth over a
mine will eventually consolidate, so the mine location should have a small
mound immediately after laying (Figure 5-7). Ensure that the mound is
inconspicuous and that it blends with the surrounding area. It is very
important that you make a final check after concealing each mine so that you
can correct faults progressively, because they cannot be corrected later.

AT mines in standard-pattern minefields should be buried. However if
conditions dictate, mines with a single-impulse fuse may be laid on the
surface. Mines with double-impulse fuses should always be buried, because if

5-6 Conventional Mines

FM 20-32

prevent tipping.

Make steep slopes to \ mt

i

Ensure that the mine has
a firm, level base.

Figure 5-6. Buried mine with tilt rod

RIGHT -The hole is much
larger than the mine and the
pressure plate is 5 cm below
the surface (AT mines).

RIGHT - A small mound is
left and covered with the
original sod or camouflage.

W f

WRONG -The mine
is too deep.

WRONG - A depression is
left and not camouflaged.

WRONG - The hole
is too small.

Figure 5-7. Buried and concealed mines

Conventional Mines 5-7

C2, FM 20-32

they are surface-laid, they may be physically damaged when pressure is
exerted by a tracked vehicle. Buried mines also have some resistance to
countermeasures, but surface-laid mines have none. Consideration must also
be given to sympathetic detonation of AT mines (Table 5-3). US conventional
mines do not have integral AHDs, so allow extra time to lay mines with AHDs.

Table 5-3. Sympathetic detonation chart

Type

M16

M15

M19

Surface-laid

NA

4.0 m

4.0 m

Buried flush

1.5 m

2.4 m

5.5 m

Buried 5 cm

NA

1.5 m

4.8 m

The difficulty of burying mines in very rocky ground and the necessity for
surface laying will have a bearing on which mines are suitable. For example,
small, blast -type AP mines are hard to detect and easy to camouflage. They
are much easier to camouflage than larger fragmentation mines. The type of
AT mine used will make little difference, because the mine's size will always
make camouflage very difficult.

Maneuver Assistance

During large mine-laying operations, engineers seldom have sufficient
manpower to carry out all minefield tasks. Other combat arms units must
often provide work parties. Engineers must be capable of organizing,
controlling, and supervising combined arms work parties. They must also
instruct them in new equipment and techniques. Work parties may be
integrated with engineers or given certain tasks that are within their
capabilities.

When laying a standard-pattern minefield, consider supplementing work
parties with other combat arms soldiers to perform the following:

• Executing Class IVA/ supply point or mine dump missions. Soldiers
uncrate and prepare mines and remove empty boxes and residue.

• Laying. Soldiers position mines within strips and dig holes.

• Marking. Soldiers construct the perimeter fence and emplace mine
signs.

Unpacking, preparing, and loading mines are the most time-consuming tasks
when laying a row minefield; and they are ideal tasks for other combat arms
soldiers.

5-8 Conventional Mines

This chapter implements STANAG 2036.

USE

Chapter 6

Row Mining

Row mining is a means of emplacement for tactical minefields. For
example, a typical tactical minefield could contain several rows of
regularly spaced mines.

Row mining is not a new idea. It has been used si nee the beginning of modern
mine warfare and is very effective. It is especially effective in support of
maneuver-oriented doctrine. Row mining is faster than standard-pattern
mining and improves the maneuver commander's flexibility by providing him
an obstacle that requires less manpower effort.

Mines may be surface-laid or buried, and they are often laid directly from a
slow-moving vehicle. This reduces the time and the personnel required to
emplace a minefield. Row mining can be used as a tactical or situational
obstacle. Minefields are usually emplaced at or near the FLOT, along flank
AAs, to support security operations. Speed and efficiency make row mining a
desirable option, and row mining supports current doctrine.

RULES

Rules governing authority, reporting, recording, and marking are generally
the same for row minefields as they are for other minefields. Row mining is
simply a method of laying mines.

The most important factor in row mining is the requirement for strict C 2 . Row
mining is potentially the most hazardous form of mine laying. It entails
vehicles and personnel moving in and around mines without the safety of a
centerline strip. Leaders must place extreme emphasis on safety because the
laying procedure is very rapid.

Most of the rules governing row mining are defined in STANAG 2036. A
summary of those rules and some additional rules that apply are shown below.

• Rows.

— There are two types of mine rows— regular and short. Short rows
are described under IOE rules below.

— Regular rows are marked and recorded. They are designated by
letters (A, B, and so forth), with Row A being closest to the enemy.

— The minimum distance between rows of AT mines is 8 meters.

— Korea Only: The minimum distance between any row and a
row containing AP mines is 15 meters.

Row Mining 6-1

FM 20-32

— The distance between the start row marker and the first mine in a
row is the mine spacing for that row.

— Start and end row markers are permanent markers and must be
made of detectable material.

• Clusters.

— Clusters are placed on the row centerline and directed toward the
enemy side.

— A cluster in row mining usually consists of one AT mine (Korea
Only: but it may also contain AP mines).

— Cluster composition must remain the same throughout the row.

— Korea Only: Different types of AP mines may be used in a
cluster.

— Korea Only: The total number of mines in one cluster will
not exceed five; no more than one will be an AT mine.

— The type of AT mine may vary from one cluster to another.

— Korea Only: A cluster of AP mines can be laid in a 2-meter
semicircle on the enemy side of the baseline.

— When a cluster contains a mine that is equipped with an AHD, the
mine is armed before the AHD is armed. The cluster is not armed
until all personnel are at least 60 meters away.

— Omitted clusters do not contain mines. They are recorded on DA
Form 1355 (see Chapter 8).

— Clusters are omitted within lanes, within gaps, in areas less than
2 meters from boundaries and lanes, and in areas where the
terrain (trees, rocks) prohibits emplacement.

• IOE.

— The IOE is located on the enemy side of the minefield.

— The IOE baseline must beat least 15 meters from Row A.

— IOE mines are buried.

— IOE short rows are labeled at start (II) and end (HE) points.

— I OE short rows must be at least 15 meters apart.

• Korea Only: Trip wires.

— Trip wires can be used in regular rows, but only one mine
per cluster can be actuated by a trip wire.

— No more than two trip wires can be used on a mine.

— Trip wires are not considered AH Ds.

— Trip wires must be at least 2 meters from a minefield lane,
a cluster, another trip wire, an IOE short row, or a
minefield perimeter fence.

6-2 Row Mining

FM 20-32

— Trip wires can only be used with AP fragmentation mines.

• Lanes.

— Lanes are sited before laying begins. Lane locations should not be
obvious.

— Clusters must be at least 2 meters from lane edges.

— The number of lanes must be sufficient to ensure that no one lane
is overused and turned into an obvious track.

— Sufficient mines must be stockpiled so that the responsible unit
can seal lanes suspected of being located by the enemy.

• General.

— The spacing between mines or clusters can vary from 4 to 10
meters but must remain constant within the row.

— M ines and clusters must be at least 15 meters from the perimeter
fence.

— If the distance between a mine or a cluster and any turning point
is less than the spacing for that row, omit that mine or cluster. The
mine immediately following a turning point is always located at
the mi ne spaci ng for that row.

— The minefield has two landmarks located to the rear, never to the
extreme side or front.

— Global-positioning systems (GPSs) can only be used to determine
the coordinates for minefield landmarks and reference points
(RPs).

WARNING
Do not use GPSs to chart or record minefield perimeter coordinates
or to determine safe routes through or around existing minefields.

LOGISTICS

Calculations

If landmarks are more than 200 meters away from the last row or
are out of the direct line of sight, intermediate row markers or
landmarks are placed at least 75 meters from the last end row
marker.

Landmarks can be used for morethan one minefield. This must be
recorded in the remarks block of DA Form 1355.

Back azimuths are not used to record the minefield.

Measurements are in meters.

To simplify the calculation process, a minefield requirements computation
work sheet (Figure 6-1, pages 6-5 through 6-8) has been developed. This work
sheet is provided to the platoon leader or sergeant as a step-by-step guide to
the mathematics involved in the logistical computation process. Properly

Row Mining 6-3

FM 20-32

completed, the work sheet provides the number of mines to order (by type), the
number of regular strips to be emplaced, cluster composition, the estimated
man-hours required to install the minefield, the amount of fencing and
marking material required, the number of truckloads required to carry the
mines, and the number of rolls of engineer tape required.

Step-by-step procedures for completing the work sheet are shown in Figure 6-2,
pages 6-9 through 6-14. Each step is explained in the exampleto facilitate the
understanding of the logic behind the calculations.

Use the foil owing steps to determine the number of AT mines required for a
row minefield when not using the standard row minefields discussed later in
this chapter. Round the resulting numbers up to the nearest whole number.

Step 1. Determine the number of mines required.

density x front = number of mines

Step 2. Determine the number of mines per row.

front ■*• mine Spacing = number of mines per row

Step 3. Determine the number of rows.

number of mines ■*■ number of mines per row = number of rows

Step 4. Determine the actual number of mines.

number of mines per row x number of rows = number of mines

Step 5. Determine the number of mines to request (includes a 10 percent
resource factor).

number of mines x 1.1 = number of mines to request

Step 6. Determine the number of vehicle loads by using Table 2-8, page 2-45.

Step 7. Determine the fencing and marking material required.

Sample Problem: Your platoon has been tasked to emplace a 400-meter row
minefield with a density of 0.5-0-0 (AT-AP fragmentation-AP blast). You have
decided to space the mines 6 meters apart. Determine the number of M15
mines to order and the number of 5-ton dump trucks (with sideboards)
required to deliver the mines.

Step 1. 0.5 x400 meters =200 mines

Step 2. 400 -6 =66.6 =67 mines per row

Step 3. 200-67 =2.98 =3 rows

Step 4. 67 x 3 = 201 mi nes

Step 5. 201 x 1.1 =221.1 =222 mines

Step 6. 222 -204 =1.08 =2 5-ton trucks

Step 7.

— Concertina: ([400 x 2] + [200 x 2] + 160) x 1.4 = 1,904 meters of
concertina

— Pickets: 1,904-15 =126.9 =127 pickets

— Signs: 127 pickets =127 signs

6-4 Row Mining

FM 20-32

MINEFIELD REQUIREMENTS COMPUTATION WORK SHEET

GIVEN

Desired density

AT APF APB

IOE representative cluster

AT APF APB

Front

meters

Depth

meters

Percentage of AHDs

%

Type of mines

AT APF APB

Type of truck/trailer
Lanes/gaps/traffic tapes
Trip-wire safety tapes
PART 1 . NUMBER OF MINES

A. IOE live clusters = front -=- 9

-=-9 = (round up)

AT APF APB

B. IOE representative cluster x
Number of IOE clusters =

XXX

Number of mines in IOE

C. Desired density x
Minefield front =

XXX

Mines in regular strips

D. Subtotal of mines
(line B + line C)

E. 10% excess factor =

x1.10 x1.10 x1.10

Total number of mines to order
(round up for each)

PART 2. NUMBER OF REGULAR STRIPS

A. Add desired density

B. 0.6 x line A above

AT + APF + APB
0.6 x = (round up)

_

C. 3 x AT desired density

3x

Figure 6-1. Minefield requirements computation work sheet

Row Mining 6-5

FM 20-32

D. Number of regular strips required = highest number of line B or C
PART 3. NUMBER OF AHDs

% AHDs x total number of AT mines

PART 4. STRIP CLUSTER COMPOSITION
A. Desired density

AT: 3 x = APF:3 x = APB: 3 x

B. Cluster composition table

STRIP AT APF APB STRIP TOTAL

(cannot exceed 5)

A

B

C

D

E

F

G

H

I

TOTAL

(Cannot exceed

desired density x 3

as computed in A above)

PART 5. NUMBER OF MAN-HOURS FOR INSTALLATION

Number of mines -=- emplacement rate = mines per man-hour

Number of AT mines: -=- 4 = (round up)

Number of APF mines: -=- 8 = (round up)

Number of APB mines: -=-16 = (round up)

+ + x 1 .2 = man-hours (round up)

Figure 6-1 . Minefield requirements computation work sheet (continued)

6-6 Row Mining

FM 20-32

PART 6. AMOUNT OF FENCING AND MARKING MATERIAL

A. Concertina wire or single-strand barbwire

([front x 2] + [depth x 2] + 160) x 1.4 = meters of concertina or single-strand barbwire required

([ *2] + [ x2] + 160) x 1.4= (roundup)

Number of pickets = amount of concertina or single-strand barbwire -=- 15

-=-15 = (round up)

-OR-

B. Double-strand barbwire

([front x 2] + [depth x 2] + 160) x 2.8 = meters of double-strand barbwire required

([ *2] = [ x2] + 160) x 2.8= (roundup)

Number of pickets = amount of double-strand barbwire -=- 30
-=- 30 = (round up)

C. Number of signs = number of pickets =

PART 7. NUMBER OF TRUCKLOADS

AT mines

cases per truck x mines per case = mines per truck

mines required -=- mines per truck = truckloads of AT mines

APF mines

cases per truck x mines per case ■

mines required -=- mines per truck =

APB mines

. cases per truck
mines required -

mines per case ■■

mines per truck
truckloads of APF mines

mines per truck

mines per truck = truckloads of APB mines

Total truckloads

AT truckloads + APF truckloads

APB truckloads

total truckloads required (round up)

Figure 6-1. Minefield requirements computation work sheet (continued)

Row Mining 6-7

FM 20-32

PART 8. AMOUNT OF ENGINEER TAPE

A. Minefield boundaries

B. Regular strips

C. IOE

depth x 2 = x 2 =

front x number of reqular strips x

front + (number of IOE clusters x 3) = + ( x 3) =

D. Lanes and gaps

E. Traffic tapes

F. Trip-wire safety tape

G. Subtotal (lines A + B -

depth x 2 x number of lanes and qaps = x 2 x

depth x number of traffic tapes x

front x number of reqular strips with trip wire x

h C + D + E + F)

+

+ + + + meters (round up)

H. Number of rolls to order (line G x 1 .2)

x 1.2 =
meters -;
PART 9. SANDBAGS

meters

1 70 meters per roll = rolls of engineer tape (round up)

A. Number of clusters in

IOE (from 1A) =

B. Number of clusters in

minefield = number of clusters in IOE x 3 x number of regular strips (from 2D) =
jrs (line A + line B) =

C. Total number of cluste

D. Number of sandbags

= number of clusters x 3 sandbags per cluster (line C x 3) =

Figure 6-1. Minefield requirements computation work sheet (continued)

6-8 Row Mining

C2, FM 20-32

Basic information pertaining to the minefield is normally determined by the engineer company commander
or the staff engineer. It is provided to the OIC or NCOIC of the emplacing unit during the mission briefing.
In this example, the following guidance is given to the emplacing unit:

Desired density

AT1

APF4

APB8

IOE representative cluster

AT1

APF2

APB2

Front

200 meters

Depth

300 meters

Percentage of AHDs

10%

Type of mines

ATM15

APFM16A2

APBM14

Type of truck/trailer

5-ton dump (with

sideboards)

Lanes/gaps/traffic tapes

1 lane, 1 traffic tape (foot troops)

Trip-wire safety tapes

3

The rest of this work sheet is completed by using the above information.

The regular strip has a cluster density of one cluster every 3 meters. The IOE has a cluster density of one-
third that of a regular strip, or one cluster every 9 meters. Therefore, to obtain the number of clusters in the
IOE, the length of the strip is divided by 9. Decimals are rounded up to the next higher whole number.

PART 1 . NUMBER OF MINES

Step 1 .

IOE live clusters 200 -=- 9 = 23 (rounded up)

The representative cluster composition for the IOE clusters is established and provided by the commander
based on METT-TC factors. The number of clusters in the IOE is multiplied by the cluster composition to
determine the number of mines, by type, in the entire IOE.

Step 2.

AT

APF

APB

IOE representative cluster x

1

2

2

Number of IOE clusters =

23

23

23

Number of mines in IOE

23

46

46

The minefield front multiplied by the desired density determines the number of mines in the minefield.

NOTE: The desired density pertains only to the regular strips and does not take into account the
number of mines in the IOE which were calculated in Step 2.

Figure 6-2. Step-by-step procedures for completing the minefield requirements

computation work sheet

Row Mining 6-9

FM 20-32

Step 3.

Desired density x 14 8

Minefield front = 200 200 200

Mines in regular strips 200 800 1,600

The number of mines required for the IOE (Step 2) is added to the number of mines in the regular strips
(Step 3).

Step 4. Subtotal of mines

(Step 2 + 3) 223 846 1,646

Ten percent is added to the total number of mines required to allow for damaged items and irregularities in
terrain and strip length. This is accomplished by multiplying the total number of mines (Step 4) by 1 .1 . Dec-
imals are rounded up to the next higher whole number.

Step 5.

1 0% excess factor = 1.1 1.1 1.1

Total number of mines to order 246 931 1,811

These figures represent the total number of mines, by type, required for the entire minefield. When order-
ing by the case rather than by individual mines, the total should be divided by the number of mines per
case and rounded up to the next whole case. (See Table 2-8, page 2-45.)

PART 2. NUMBER OF REGULAR STRIPS

Step 1 .

Add desired density AT 1 + APF 4 + APB 8 = 13

Each regular mine strip has a cluster every 3 meters; therefore, its density is one-third cluster per meter of
front. A total density of 1 3 mines per meter of front in the previous example would equal 3 x 1 3 or 39 mines
per 3 meters of front. Clusters may contain a maximum of five mines, so the resulting figure must be
divided by 5. In short, to determine the minimum number of regular strips required, the total density must
be multiplied by three-fifths (3 meters between clusters and five mines per cluster). For ease of calculation,
three-fifths is converted to the decimal 0.6. Decimals are rounded up to the next highest whole number.

Step 2.

0.6 x Step 1 0.6 x 13 = 8 (rounded up)

The calculations to determine the minimum number of regular strips previously described are not suitable
when the ratio of AT to AP mines is greater than 1 :4. For example, if the desired density is 1 -1 -1 , the total
density is 3. The minimum number of strips would be 3 x 3/5 = 1 .8, rounded up to 2 strips. However,
because of the restriction on the number of AT mines per cluster, it is impossible to obtain a density of 1 AT
mine per meter of front with only 2 strips. A minimum of 3 regular strips is required. The alternative means
of determining the number of regular strips is founded by multiplying the AT desired density by 3.

Figure 6-2. Step-by-step procedures for completing the minefield requirements
computation work sheet (continued)

6-10 Row Mining

FM 20-32

Step 3.

3 x AT desired density 3x1=3

The number of regular strips calculated by the first method and the alternative method are compared, and
the higher figure is used as the minimum number of regular strips. The 8 determined by the 3/5 rule is
larger than the 3 determined by the alternative method. Therefore, the minimum number of regular strips in
the example is 8.

Step 4.

Number of regular strips required = highest number of Step 2 or 3 = 8
PART 3. NUMBER OF AHDs

0.1 x 223 = 23 (rounded up)

PART 4. STRIP CLUSTER COMPOSITION

The cluster composition table is prepared by the OIC of the laying unit to control the allocation of mines to
a regular strip. The cluster composition remains constant within a particular strip, but it may vary among
different strips. As the mines are allocated by strip, no more than 1 AT mine can be placed in each repre-
sentative cluster, and each cluster can have a maximum of 5 mines.

A tabular format is prepared (see Figure 6-1 , page 6-6) to facilitate the distribution of mines by emplace-
ment personnel. Note that each component of the desired density is multiplied by 3. The number 3 is
always used regardless of the minimum number of regular strips because it is the number of mine strips
required to give a minefield density of 1 mine per meter of front when a cluster contains only 1 mine of
each type. Each mine strip has a cluster every 3 meters; therefore, it has a density of one-third mine per
meter when a cluster contains 1 of each type of mine.

Step 1 . Desired density

AT:3x1=3 APF:3x4 = 12 APB: 3 x 8 = 24

The total of each column in the table cannot exceed the number of mines above. For example, with an APF
desired density of 4, 3 x 4 = 12, so the total APF mines in the representative cluster composition for each
of the regular strips cannot exceed 12.

PART 5. NUMBER OF MAN-HOURS FOR INSTALLATION

Remember, the total number of mines includes the mines in regular strips and the mines in IOE short
strips. The laying rates are —

AT mines: 4 per man-hour.

APF mines: 8 per man-hour.

APB mines: 16 per man-hour.

Figure 6-2. Step-by-step procedures for completing the minefield requirements
computation work sheet (continued)

Row Mining 6-11

FM 20-32

The number of man-hours required for each mine type is computed and rounded up. These amounts are
totalled and a 20 percent excess factor is included by multiplying the total by 1 .2. The resulting figure is the
total number of man-hours required for emplacement and represents straight work time only. It does not
take into account the time for transportation to and from the emplacement site, meals, and breaks; limited
visibility; or NBC conditions. The commander should use his judgment and past experience to determine
the time required for transportation, meals, and breaks. When working under limited visibility or NBC con-
ditions, the total man-hours (after the excess factor has been included) should be multiplied by 1.5.

In this example, a total of 357 man-hours is required as determined below. Note that each decimal is
rounded to the next higher whole number.

Number of mines -=- emplacement rate = mines per man-hour

Number of AT mines 246 -=- 4 = 62 (rounded up)

Number of APF mines 961 -=- 8 = 121 (rounded up)

Number of APB mines 1,811 -=- 16 = 114 (rounded up)

Total 62 + 1 21 + 1 1 4 = 297 x 1 .2 = 357 (rounded up)

PART 6. AMOUNT OF FENCING AND MARKING MATERIAL

Standard-pattern minefields must be marked and fenced. The amount of fencing required depends on
whether barbwire (single- or double-strand) or concertina is used.

The amount of wire for a single-strand barbwire or a single-strand concertina fence is calculated with the
following formula:

([front x 2] + [depth x 2] + 1 60) x 1 .4
The amount of wire for a double-strand barbwire fence is calculated with the following formula:

([front x 2] + [depth x 2] + 160) x 2.8
Step 1 .
Concertina Wire or Single-Strand Barbwire

([200 x 2] + [300 x 2] + 1 60) x 1 .4 = 1 ,624
The number of pickets required is determined by dividing the total amount of fence by 1 5.

Number of pickets = amount of fence -=-15 1 ,624 -=- 1 5 = 1 09 (rounded up)
Step 2.
Double-Strand Barbwire

([200 x 2] + [300 x 2] + 160) x 2.8 = 3,248 (rounded up)
The number of pickets required is determined by dividing the total amount of fence by 30.

Number of pickets = amount of fence -=- 30 3,248 -=- 30 = 1 09 (rounded up)

Figure 6-2. Step-by-step procedures for completing the minefield requirements
computation work sheet (continued)

6-12 Row Mining

FM 20-32

The number of minefield marking signs is equal to the number of pickets.

NOTE: These calculations determine the marking and fencing materials required for the minefield
perimeter only. Additional materials may be required for lanes and gaps.

PART 7. NUMBER OF TRUCKLOADS

The number of vehicles required depends on the type and amount of mines as well as the type of vehicles
available. The total mines, by type, required is divided by the haul capacity of available vehicles to deter-
mine the number of truckloads required to transport the mines.

In this example, crated M15 AT mines, M16A2 APF mines, and M14 APB mines are hauled in M930 5-ton
dump trucks (with sideboards). (See Table 2-8, page 2-45).

AT mines:

246 mines required -=- 204 mines per truck = 1 .2 truckloads of AT mines
APF mines:

931 mines required -=- 888 mines per truck = 1 .05 truckloads of APF mines
APB mines:

1,811 mines required -=- 13,770 mines per truck = 0.13 truckloads of APB mines

Total truckloads:

1 .2 AT truckloads + 1 .05 APF truckloads + 0.1 3 APB truckloads = 2.38 truckloads = 3 truckloads
(rounded up) required

PART 8. AMOUNT OF ENGINEER TAPE

An extensive amount of engineer tape is used to mark the initial layout of a standard-pattern minefield.
Engineer tape comes in 1 70-meter rolls and is used to mark several portions of the minefield.

NOTE: In this example, only one lane and one roll of traffic tape is required.

Step 1 .

Minefield boundaries depth x 2 300 x 2 = 600

Step 2.

Regular strips

Step 3.

IOE

Step 4.

Lanes and gaps

Step 5.

Traffic tape

front x number of regular strips

front + (number of IOE clusters x 3)

depth x 2 x number of lanes and gaps

depth x number of traffic tapes

200 x 8 = 1 ,600

200 + (23 x 3) = 269

300 x 2 x 1 = 600

300 x 1 = 300

Figure 6-2. Step-by-step procedures for completing the minefield requirements
computation work sheet (continued)

Row Mining 6-13

FM 20-32

Step 6.

Trip-wire safety tape

front x number of regular strips with trip wire 200 x 3 =

= 600

Step 7.

Total of Steps 1 through 6 = 600 + 1 ,600 + 269 + 600 + 300 + 600 = 3,969 meters

Step 8.

Add 20% excess

total amount of engineer tape required for the minefield x 1 .2 =
3,969 x 1 .2 = 4,762.8 = 4,763 (rounded up)

Step 9.

Total number of rolls

total amount of engineer tape, in meters, from Step 8 -=-
170 meters per roll = 4,763 meters -=- 170 = 28.02 = 29 rolls

PART 9. SANDBAGS

To determine the num

ber of sandbags for the removal of spoil.

Step 1 .

Number of clusters in

IOE (Parti, Step 1) = 23

Step 2.

Number of clusters in

minefield = number of clusters in IOE x 3 x number of regular strips (Part 1 , Step 4)

23 x 3 x 8 =

552

Step 3.

Total number of clusters (add Steps 1 and 2) = 575

Step 4.

Number of sandbags

= number of clusters x 3 sandbags per cluster

575x3 = 1,725

Figure 6-2. Step-by-step procedures for completing the minefield requirements
computation work sheet (continued)

Task Organization

To maximize the efficiency of the row-mining process, the platoon leader must
task-organize his platoon. The organization of thetask, as a whole, is intricate
and places great demands on the leader. Leave nothing to chance when
planning and executing a row minefield, because each situation is different.
Make allowances for transporting, handling, and controlling the mines. The
officer in charge (OIC) and the squad leaders must be able to exercise control
throughout thetask under all conditions. Always observe safety.

Organize the platoon into four parties— siting and recording, marking, mine
dump, and laying.

6-14 Row Mining

FM 20-32

Siting-and-Recording Party

Marking Party

The platoon leader directs the party and is responsible for siting, recording,
and reporting the minefield. This party consists of one or two soldiers and a
vehicle to carry material. (If a vehicle is not available, increase the party to
three soldiers.) Because siting is usually done in daylight, the party must take
appropriate physical-security measures. The party starts well ahead of the
actual laying, sets out control markers, and avoids using sharp turns. The
party marks the vehicle traffic routes to and from the minefield rows.

When siting is complete, the 01 C identifies one member of the party to be the
recorder and assigns the remaining soldiers to other tasks. The recorder
collects data from the laying party NCOIC and completes DA Form 1355 as
outlined in Chapter 8. TheOIC ensures that the DA Form 1355 is completed
timely and accurately.

This party is composed of an NCOIC and personnel who are not working as
members of other teams. After the minefield is sited, the marking party
emplaces fence posts, wire, and marking signs.

Mine-Dump Party

Laying Party

This party is controlled by the platoon sergeant (PSG) and is composed of
personnel who are not working as members of other teams. The mine-dump
party accounts for all strip packages that arrive from other sources, sets up
vehicle mine sets at the mine dump, and hauls supplies as required. The PSG
places row packages in a location that maximizes speed and provides
concealment for minefield emplacement, and he also ensures that the mine
dump is prepared for night operations. The party marks the mine dump's
entrance and exit and the routes to them. The PSG verifies the strip feeder
reports with the squad leaders upon the completion of each row and passes
the reports to the recording party. The PSG is not required tostay at the mine
dump continuously; he has the flexibility to move around the area to perform
other activities.

The mine-dump party creates vehicle sets by setting aside the number of
mines and fuses that are required by each laying vehicle. The party loosens
and then hand-tightens arming and shipping plugs, helps load the mines onto
laying vehicles, and disposes of residue. Soldiers may also assist the marking
party and provide local security. For initial vehicle loads, the mine-dump party
may be assisted by the laying party.

This party consists of an NCOIC, four soldiers, and a vehicle to carry the
mines. The NCOIC controls the movement of each laying vehicle. He directs
each vehicle to start and stop laying and controls immediate-action drills. The
NCOIC initiates a strip feeder report with the PSG or the mine-dump NCOIC,
receives azimuths from the siting party, and directs his element to the correct
row. He is responsible for replacing the temporary row markers with
permanent markers and for ensuring that mines are laid according to the
azimuths, mines are spaced correctly, and the strip feeder report is accurate.

Row Mining 6-15

FM 20-32

Carrier Team

Sapper Team

Digging Team

Site Layout

Mine Rows

TheNCOIC ensures that the end row marker isemplaced at the completion of
each row, and he closes the strip feeder report with the PSG.

NOTE: Using tilt-rod fuses requires additional soldiers to stake
mines, insert fuses, and arm mines.

When laying three rows at once, each laying party consists of an APC or an
organic squad vehicle and a carrier, sapper, and digging team.

This team is comprised of the APC driver and the track commander (TC).
They ensure that the APC maintains the proper speed and stays on the proper
course.

This team is composed of the squad leader and the remaining squad members.
It provides personnel to lay and arm mines. Each soldier carries wrenches and
fuses. The squad leader supervises laying and tasks personnel who are not
needed for laying toother parties.

The digging team buries mines. It consists of an NCOIC and several soldiers
(may be soldiers from supported maneuver units) who are equipped with
suitable digging tools. Increase the arming party by two to speed up the laying
process or task personnel who are not needed to other parties. NOTE: If
mines are surface-laid, there is no digging team.

Once the platoon leader has coordinated the location of the minefield(s) with
the maneuver commander, siting in the minefield can begin. Siting is the first
step in the actual laying process and is done for safety and control. Although
the minefield may beemplaced at night or during limited visibility, the siting
party should site the minefield under favorable conditions, preferably during
daylight. Siting consists of identifying landmarks; establishing routes; and
emplacing start, end, and intermediate row markers. Actual control measures
(stakes or pickets) should not stand out to such an extent that they give away
the minefield orientation, but they must be easily discernible to the laying
party.

Certain features, like thick woods and deep, wide streams, are natural
obstacles. Mine rows should be laid to reinforce terrain and increase the
effectiveness of the minefield.

M ine rows are labeled with a letter and should be laid in order. Row A is
nearest the enemy, followed by rows B, C, D, E, and so forth. When laying
tactical minefields, each row has permanent start and end row markers.
I ntermediate markers may be required, depending on the row length and the
terrain. Platoon leaders determine the number of laying vehicles to be
employed. The preferred technique is to use three vehicles so that three rows
can be laid simultaneously. Using more than three vehicles is beyond the

6-16 Row Mining

Mine Spacing

FM 20-32

platoon's C 2 capabilities and is not considered. The distance between rows is
determined by the following factors:

• Depth and density of the minefield.

• Terrain.

• Suitability of theground.

• Desired obstacle intent.

NOTE: Rows are spaced 50 meters apart in standardized row
minefields (discussed later in this chapter).

The minefield 01 C determines the mine spacing. The desired density, the
availability of laying vehicles, the number of rows, and the possibility of
sympathetic detonation (Table 5-3, page 5-8) affect the distance between
mines. NOTE: Mines are spaced 6 meters apart in standardized row
minefields (discussed later in this chapter).

Control Measures

Control measures are temporary markers that are used to guide vehicles and
troops during row-mining operations. Markers are constructed of different
materials for different uses. For example, use VS17 panels on poles for start
and end row markers, and use M133 hand-emplaced minefield marking set
(H E M M S) poles with flags for intermediate markers. Use the following
temporary markers:

• Start row (does not replace the mandatory permanent marker).

• Start laying (first intermediate marker after the start row marker).

• I ntermediate (used between the last row marker and the next visible
point, not more than 100 meters away).

• Change of direction or turning point (actually consists of three
markers— warning, turning point, and new direction).

• Stop laying.

• End row (does not replace the mandatory permanent marker).
The following materials may be used to construct temporary markers:

U-shaped pickets.

• HEM MS poles.

• Wooden posts.

• Steel rods.

• Engineer tape.

• VS17 panels.

Control measures for laying mines at night require lights or infrared (IR)
equipment as follows:

• Chem-lights placed in U-shaped pickets or hand-held.

Row Mining 6-17

FM 20-32

Procedures

• Directional flashlights taped in U-shaped pickets or hand-held.

• HEMMS lights used with U-shaped pickets or poles.

• Lights from a minefield marking set number 2.

• IR reflectors.

NOTE : The use of control measures should be incorporated into unit
standard operating procedures (SOPs).

The minefield 01 C arrives on the site with thesiting-and-recording party. He
selects Landmark 1 and then sites the left (or right) boundary fence and start
row markers (all start and end row markers are permanent markers). The
siting-and-recording party takes distances and azimuths to be used in
preparing the recording form. If the tactical situation permits and the
marking party is ready, emplacement of the fence should begin.

If the minefield is to have an IOE row, thesiting-and-recording party proceeds
across the IOE and establishes II, HE, 12, I2E, and soon until it reaches the
end. Personnel proceed down the right (or left) boundary and emplace start
row marker Al. Proceeding from Al toA2, they place intermediate markers as
required. Personnel use different colored markers to identify each row (for
example: Row A, red light; Row B, green light; Row C, blue light). For I R
markings, they use multiple horizontal I R light sources that are spaced at
least 6 inches apart (for example: Row A, one light; Row B, two lights; Row C,
three lights). When they reach A2, they emplace an end row marker and
repeat the procedure from Bl toB2, CI toC2, and soon until they emplace all
the required control measures (Figure 6-3). The siting-and-recording party
establishes Landmark 2 and the left (or right) rear fence location. Personnel
also assist thePSG in siting mine dumps near the minefield.

Mine-Laying Vehicles

Soldiers normally lay row minefields from a tactical vehicle. Consider
vulnerability, capacity, and trafficability when selecting a vehicle. Before
emplacing the minefield and preparing the vehicle for mine laying, drive it in
a random pattern across the minefield site. The random pattern deceives the
enemy by masking the actual laying pattern. Load enough mines so that each
vehicle can complete at least one entire row before reloading, but do not stack
fused mines morethan two-high.

Laying a Row Minefield

The following drills demonstrate how to lay a minefield:

Drill 1

Squad vehicles arrive on the site and proceed down the left (or right) boundary
of the minefield to their assigned row. (A separate party must be detailed to
install the IOE.) At the start row marker, the squad vehicle moves into
position and prepares to lay mines. The squad leader for Row A directs Vehicle
1 to move out.

Mines are laid on the ground at the required spacing, along the temporary
markers positioned by thesiting-and-recording party.

6-18 Row Mining

FM 20-32

Start

row

markers

▲ Landmark 1

A'

Landmark 2

Mine dump

Figure 6-3. Site layout

As mines are laid, the arming party moves behind the vehicle and arms the
mines. Personnel remove temporary markers installed by the siting-and-
recording party and replace the end row markers with permanent markers.

When Vehicle 1 moves a safe distance (approximately 25 meters) along Row A,
Vehicle 2 begins to lay mines on Row B. When Vehicle 2 moves a safe distance
along Row B, Vehicle 3 begins to lay mines on Row C.

The marking party continues to empl ace the left and right boundary fences
(Figure 6-4a, page 6-20).

The IOE party exits the minefield outside the left (or right) boundary after it
completes the I OE.

When Vehicles 1 and 2 finish their assigned rows, they move past the end row
marker and execute a left (or right) turn and wait for Vehicle 3 to complete its
row. All vehicles move in column down the left (or right) boundary to the mine
dump, load the next row's mines, and then move to their next assigned row.
The process of laying and arming mines is repeated (Figure 6-4b, page 6-21).

After the minefield is laid, all the vehicles exit down the left (or right)
boundary and out the rear. The marking party completes the rear boundary
fence, and the recording party completes DA Form 1355. The 01 C or PSG
ensures that the DA Form 1355 is complete and accurate and signs it.

Row Mining 6-19

FM 20-32

Drill 2

Figure 6-4a. Laying a minefield

This drill may be used to speed up mine laying; however, strict C 2 is vital to
ensure security and safety. This method is difficult to use when the terrain is
rugged or when weather or visibility is subject to change.

The drill is conducted by three squad vehicles, each laying one row. Row B has
turning points and Rows A and C do not. If the minefield has six rows, Row E
has turning points and Rows D and F do not. The squad leader (laying leader)
in Row B (and Row E, if required) is in charge of the overall laying.

Squad vehicles arrive on the site and proceed down the left (or right) boundary
of the minefield to their assigned row. Squad vehicles move into position at
start row markers and prepare to lay mines.

The laying leader directs Vehicle 1 to move out on Row A. The sapper team
lays mines on the ground at the required spacing. If an IOE is required, the
Row A team emplaces the IOE concurrently with Row A and at the same
spacing. When Vehicle 1 reaches the IOE short-row start marker, the laying
party lays mines along an azimuth designated by the laying leader (Figure 6-
5). After the IOE short row is laid, Vehicle 1 returns to Row A and continues
laying mines.

6-20 Row Mining

FM 20-32

Figure 6-4b. Laying a minefield (continued)

A.

First mine in the IOE
short row

<5\

^

o-

Row A

15 r

6 m

Figure 6-5. Laying an IOE short row

Row Mining 6-21

FM 20-32

After all the mines are laid, the arming party moves behind the vehicle and
arms the mines. Personnel remove temporary markers and replace start and
end row markers with permanent markers. The arming party must be
distinguishable from everyone else. The last member of the arming party
should wear a colored vest or carry a specific colored chem-light. No one is
allowed behind the last member of the arming party.

TheNCOIC completes a strip feeder report (Figure 6-6) and gives it to the
recording party. The strip feeder report includes the number of mines laid, the
type of mines laid, azimuths of IOE strips and turning points, AHDs emplaced
(by cluster number), and any other information (such as omitted mines) the
platoon leader requires.

STRIP FEEDER REPORT FOR STRIP/ROW

Type of
Mine

Number
of Mines

AHDs by
Cluster

lOE-Strip
Azimuth

Turning-Point
Azimuth

Remarks

Figure 6-6. Sample strip feeder report

Vehicle 1 moves down Row A and lays mines until the laying leader directs it
to stop. (The laying leader chooses vehicle stops to coincide with the locations
of turning points.) The laying leader then directs Vehicle 3 to begin laying
mines along Row C. Vehicle 3 lays mines on Row C until the laying leader
directs it to stop (somewhere wel I past Vehiclel).

Vehicle 2 moves toward Vehicle 1 and begins to lay mines on Row B. He lays
mines to within 15 meters of Vehicle 1. Vehicle 2 then turns toward Vehicle 3
and lays mines on Row B to within 15 meters of Vehicle 3. Vehicle 2 then turns
back toward Vehicle 1 and continues to lay mines in this pattern until Row B
is laid.

Figure 6-7 shows vehicle positions when using the above method to lay a row
minefield.

NOTES:

1. At night or during low visibility, Vehicle 1 has two red flashlights
and Vehicle 3 has two green flashlights. The flashlights are held side
by side, and pointed toward Vehicle 2. The driver of Vehicle 2 moves
forward until he is within 15 meters of the lights or until the light
holder turns the lights off.

6-22 Row Mining

FM 20-32

A2m Vehicle 1

Vehicle 20b ri
B2b

Vehicle 3d" C1
C2"

Step 1 : Vehicle 1 lays mines until it is stopped by the laying leader.

.- IOE1

l0E . 2 d-' SA1

A2 ■ VehicleT

Vehicle 2£/ B B1
B2 ■

O ■ C1

C2 ■ Vehicle 3

Step 2: Vehicle 3 lays mines until it is stopped by the laying leader.

.• IOE1

'° E . 2 d"-- IA1

A2 ■ Vehicle, -1-._

""••■B1
B2b Vehicle 2^. -*'

U «ci

C2 ■ Vehicle 3

Step 3: Vehicle 2 lays mines, turns at Vehicle 1 , and lays mines toward Vehicle 3.

IOE2 .-• .-• .--• IOE1

A2 : U m - -

Vehicle 1

A1

B2 B .' "--bBI

Vehicle 20,.'

C2 B Vehicle 3 O "C1

Step 4: Vehicle 1 repeats Step 1 , to include emplacing IOE strips.

Figure 6-7. Laying a row minefield

2. If the platoon leader feels that low visibility or other reasons
preclude the use of vehicle positions as turning points, he may have
the siting party emplace turning-point markers (three intermediate
markers) for Vehicle 2 to use as a guide. In this event, the three
vehicles emplace mines simultaneously.

After Vehicles 1 and 2 finish their assigned rows, they move past the end row
marker, execute a left (or right) turn, and wait for Vehicle 3 to complete its
row. All the vehicles move in column down the left (or right) boundary to their
next assigned row, if there is one, and continue to lay and arm mines. This

Row Mining 6-23

FM 20-32

process is repeated until the entire minefield is laid. All the vehicles then exit
the minefield down the left (or right) boundary and out the rear. The marking
party completes the rear boundary fence, and the recording party completes
DA Form 1355. The 01 C or PSG ensures that the DA Form 1355 is complete
and accurate and signs it.

Immediate-Action Drill

If the enemy attacks the platoon during minefield emplacement, the laying
party should execute the following actions:

Sapper teams enter vehicles and recover spacing sandbags.

Vehicle 1 exits the minefield by making a wide turn around the front
of the other two vehicles.

Vehicle 2 follows by making a wide turn around the front of Vehicle 3.

Vehicle 3 exits the minefield.

The three squads conduct the immediate-action drill as ordered by the
platoon leader.

Squad Drill

During row mining, the squad in each laying vehicle performs the following
actions:

• Squad leader.

— Directs the squad to start laying mines.

— Supervises mine arming and placing.

— Allocates a vehicle, if possible, to help remove spoil from the site.

• Carrier team.

— Moves the APC to the row start point.

— Lowers the APC ramp until it is horizontal or opens the rear door.
(If using the APC ramp to distribute mines, chains the ramp open
to support the weight.)

— Moves the APC at a low speed (3 to 5 kph) in a straight line toward
the row end point.

• Sapper team.

— Soldier 1 ties the rope to the end of the lowered ramp or the tow
pintle.

— Soldier 2 ties the partially filled sandbag on the other end of the
rope. (The rope length from the end of the ramp door to the
sandbag is the correct spacing between mines [Figure 6-8]).

— Soldier 3 (squad leader) positions the team members. Soldier 1 is
at the rear of the compartment, Soldier 2 sits on the edge of the
APC ramp or open door, and Soldier 4 walks behind the APC.

— Soldier 1 fuses a mine and passes it to Soldier 2. (Korea Only: If
AP mines are also laid, they are given out simultaneously.)

— Soldier 2 records all the mines issued.

— Soldier 2 places the fused mine on the ground when the sandbag
tied totheropeis even with the previously laid mine.

— Soldier 3 (squad leader) walks behind the vehicle and supervises
mine laying.

6-24 Row Mining

C2, FM 20-32

Driver

Air guard

Siting
picket

Spotter/feeder
J ^ Layer

-i 5"

Start row marker
Mine

Figure 6-8. Measuring distances between mines with sandbags

— Soldier 4 walks behind the vehicle and arms mines.

— After the mine row is armed and camouflaged, Soldier 4 buries
pins, clips, and shipping plugs 30 centimeters to the rear of the
start row marker.

— The sapper team repeats the above steps until the end of the row
is reached.

• Digging team, if needed. (The NCOIC selects the mine to be buried by
each soldier and supervises the operation.)

— Follows the laying party along the friendly side of the row.

— Digs in mines but leaves them exposed until arming is complete.

— Korea Only: Arms AP mines in a cluster before arming AT
mines.

Marking, Recording, and Reporting Row Minefields

Marking procedures for row minefields are the same as those for other
minefields (see Chapter 2).

Row minefields are recorded on DA Form 1355 (Figures 6-9a and 6-9b, pages
6-26 and 6-27). Reporting procedures for intent, initiation, status, and
completion reports are detailed in Chapter 8.

STANDARDIZED TACTICAL ROW MINEFIELDS

The specific composition of a tactical row minefield depends on METT-TC
factors and available resources. To aid in standardization of platoon
techniques, four compositions have been developed to match desired obstacle
effects. Using standardized minefields facilitates planning the obstacle type,
size, and logistical requirements. It is imperative that the design and the
effect of these minefields are well understood. They are an integral part of
combined arms obstacle doctrine and form the cornerstone of engineer
obstacle operations.

Row Mining 6-25

C2, FM 20-32

S/»mPl£

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Figure 6-9a. Sample DA Form 1355 for a row minefield (front)

6-26 Row Mining

FM 20-32

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Row Mining 6-27

FM 20-32

Disrupt and Fix

Disrupt and fix row minefields (Figure 6-10) are similarly constructed, but a
fix minefield has an IOE and does not have AH Ds.

DISRUPT

il * 6m R o w A

E m o o ° o ° ° ° o o

X o o ° ° o „ o ° ° o

8 I« o ° ° °o °°

° ° o o ° Row B

' o 00000000000000000000000000000000000000000

RowC

250 m

Disrupt

Fix

Front

250 m

250 m

Depth

100 m

120 m

Rows of AT full-width mines

1

1

Rows of AT track-width mines

2

2

IOE

No

Yes

AHD

No

No

Platoon hours required

1.5

1.5

Full-width mines

42

63

Track-width mines

84

84

Density

0.5

0.6

i

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FIX

- IOE
■ 13 Marker *■ 12 Marker ■ 11 Marker J 15m

| Row A

E

° o o „ o t^j 0w B

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RowC

250 m

Figure 6-10. Standardized disrupt and fix row minefields

6-28 Row Mining

Turn

FM 20-32

Disrupt and fix row minefields areemplaced as follows:
Row A.

— 42 full-width AT mines (tilt-rod) are placed 6 meters apart.

— No turning points.

— Mines are surface-laid (staked) or buried.

• Row B.

— Start and end row markers areemplaced 50 meters behind Row A.

— 42 track-width AT mines are placed 6 meters apart.

— Preferably no morethan 3 turning points.

— Mines are surface-laid or buried.

• Row C.

— Emplaced 100 meters behind Row A.

— 42 track-width AT mines are placed 6 meters apart.

— No turning points.

— Mines are surface-laid or buried.

• I OE (fix minefield only).

— 3 IOE short rows.

— A separate IOE baseline.

— The IOE baseline is on the enemy side, 15 meters from Row A.

— 7 full-width AT mines are placed 6 meters apart on each IOE short
row.

— Mines are buried.

— The first IOE short row is placed 48 meters from the IOE end
marker, the next short row is 84 meters from the first short row,
and the third short row is 84 meters from the second short row.

A turn minefield (Figure 6-11, page 6-30) consists of four rows of full-width
mines and two rows of track-width mines.

A turn row minefield is emplaced as follows:

Row A.

— 84 full-width AT mines (tilt-rod) are placed 6 meters apart.

— No turning points.

— Mines are surface-laid (staked) or buried.

• Row B.

— Start and end row markers areemplaced 50 meters behind Row A.

— 84 full-width AT mines (tilt-rod) are placed 6 meters apart.

Row Mining 6-29

FM 20-32

NOTE: The center of the minefield shown in this figure is
omitted for clarity.

~ T

i i
6 m

Row A

E §

8 i""

RowB

RowC

o
o

lv

fc LO

° V

o " o „

Row D

Row E

ooooooooooooooo o\ \o ooooooooooooooooooooooo

,-~~ Row F

500 m *-

r

Front

500 m

Depth

300 m

Rows of AT full-width mines

4

Rows of AT track-width mines

2

IOE

No

AHD

No

Platoon hours required

3.5

Full-width mines

336

Track-width mines

168

Density

1.0

Figure 6-11. Standardized turn row minefield

— Preferably no morethan 5 turning points.

— Mines are surface-laid (staked) or buried.
• Row C.

— Emplaced 100 meters behind Row A.

— 84 full-width AT mines (tilt-rod) are placed 6 meters apart.

— No turning points.

— Mines are surface-laid (staked) or buried.

6-30 Row Mining

Block

FM 20-32

• Row D.

— Emplaced 100 meters behind Row C.

— 84 full-width AT mines (tilt-rod) are placed 6 meters apart.

— No turning points.

— Mines are surface-laid (staked) or buried.

• Row E .

— Start and end row markers areemplaced 50 meters behind Row D.

— 84 track-width AT mines are placed 6 meters apart.

— Preferably no morethan 5 turning points.

— Mines are surface-laid or buried.

• Row F.

— Emplaced 100 meters behind Row D.

— 84 track-width AT mines are placed 6 meters apart.

— No turning points.

— Mines are surface-laid or buried.

A block minefield (Figure 6-12, page 6-32) has an IOE (Korea Only: and AP
mines) and has 20 percent AH Ds in two of its rows of full-width mines. AHDs
are placed in Rows B and C for the best effect. (Korea Only: A block
minefield also requires 84 M 16 or M14AP mines and has a density of
0.17 M16/M14 AP mine per linear meter.)

A block row minefield is emplaced as follows:

• Row A.

— 84 full-width AT mines (tilt-rod) are placed 6 meters apart.

— No turning points.

— Mines are surface-laid (staked) or buried.

• Row B.

— Start and end row markers areemplaced 50 meters behind Row A.

— 84 full-width AT mines (tilt-rod) are placed 6 meters apart.

— Preferably no morethan 5 turning points.

— Mines are surface-laid (staked) or buried.

• Row C.

— Emplaced 100 meters behind Row A.

— 84 full-width AT mines (tilt-rod) are placed 6 meters apart.

— No turning points.

Row Mining 6-31

FM 20-32

NOTE: The center of the minefield shown
' • t in this figure is omitted for clarity.

' l&marker

6 m

o

o

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it n

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Row E

Row F

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500 m

AP mine employment

V V

Front

Depth

Rows of AT full-width mines

Rows of AT track-width mines

IOE

AHD

Platoon hours required

Full-width mines

Track-width mines

AT mine density

Korea Only:
AP frag mines

Korea Only:
AP mine density

500 m

320 m

Yes

Yes

378

168

1.1

84

0.17

Figure 6-12. Standardized block row minefield

6-32 Row Mining

FM 20-32

— Mines are surface-laid (staked) or buried.

• Row D.

— Emplaced 100 meters behind Row C.

— 84 full-width AT mines (tilt-rod) are placed 6 meters apart.

— No turning points.

— Mines are surface-laid (staked) or buried.

• Row E .

— Start and end row markers areemplaced 50 meters behind Row D.

— 84 track-width AT mines are placed 6 meters apart.

— Preferably no morethan 5 turning points.

— Mines are surface-laid or buried.

• Row F.

— Emplaced 100 meters behind Row D.

— 84 track-width AT mines are placed 6 meters apart.

— No turning points.

— Mines are surface-laid or buried.

• IOE.

— 6 IOE short rows.

— A separate IOE baseline.

— 7 full-width AT mines are placed 6 meters apart on each IOE short
row.

— Mines are buried.

— The first IOE short row is placed 72 meters from the IOE end
marker, and the five subsequent IOE short rows are placed at
72-meter intervals on the IOE baseline.

• Korea Only: AP mines.

— AP mines are placed on two rows of full-width AT mines.

— AP mines are placed in a cluster around AT mines.

— One AP mine is placed in front of every other AT mine.

HASTY PROTECTIVE ROW MINEFIELDS

Hasty protective row minefields are temporary in nature and areused as part
of a unit's defensive perimeter. Units usually use mines from their basic load.
If time permits, mines should be buried to increase their effectiveness, but
they can be surface-laid. The minefield can be easily recovered becauseAHDs,
nonmetallic mines, or low-metallic mines are not used. Mines are employed
outside the hand-grenade range but within the range of small-caliber
weapons. All mines are picked up by the emplacing unit upon leaving the

Row Mining 6-33

FM 20-32

Rules

Site Layout

area, unless enemy pressure prevents mine retrieval or the minefield is being
transferred to a relieving commander.

The brigade commander has the initial authority to employ hasty protective
row minefields. This authority may be delegated to the battalion or company
commander on a mission-by-mission basis.

Most of the rules governing hasty protective row mining are defined in
STANAG 2036. A summary of those rules and some additional rules that
apply are shown below.

Rows.

Rows are marked and recorded. They are designated by letters (A,
B, and so forth) with Row A being closest to the enemy.

The minimum distance between rows of AT mines is 8 meters.

Korea Only: The minimum distance between any row and a
row containing AP mines is 15 meters.

The distance between the start row marker and the first mine in a
row is the mine spacing for that row.

An IOE row is not used.

Start and end row markers are permanent markers and must be
made of detectable material.

• General.

The spacing between mines is at least 4 meters to prevent
sympathetic detonation. There is no maximum distance between
mines within the row.

M ines are at least 15 meters from the perimeter fence.

The minefield must be fenced on all sides if M18A1 AP mines are
employed and the minefield will be in place for more than 72
hours.

The minefield has at least one landmark that is located totherear,
never to the extreme side or front.

The minefield has an easily identifiable RP (tree, stump, stake).

Back azimuths are not used to record the minefield.

Measurements are in meters.

AHDs, nonmetallic mines, or low-metallic mines are not used.

Minefields are recorded on DA Form 1355- 1-R (see Chapter 8).

Requesting and receiving permission to lay mines is the first step when
emplacing a hasty protective row minefield. The next step is conducting a
thorough leader's reconnaissance of the proposed minefield area. Identify
mine locations that cover likely AAs, enhance key weapon systems, and cover
dead space. Establish an easily identifiable RP between the minefield and the
unit position. From the RP, visualize mines as running in rows parallel to the
unit position (Figure 6-13). After the RP is established and the minefield is

6-34 Row Mining

C2, FM 20-32

visualized, complete recording and emplacethe mines, but do not arm them.
This procedure simplifies recording and makes retrieval quicker and safer.

Mine Rows

Figure 6-13. Site layout

The row closest to the enemy is designated as Row A; succeeding rows are
designated B, C, D, and so on. The ends of rows are shown by two end row
markers. They are labeled with the letter of the row and the number 1 for the
right end of the row or the number 2 for the left end of the row. The rows are
numbered from right to left, facing the enemy. The marker should bean easily
identifiable object, such as a wooden stake with a nail or a steel picket so that
it can be found with an AN/PSS-12 mine detector.

Laying Procedures

From the RP, the leader measures the magnetic azimuth, in degrees, to a
selected point on the right side (facing the enemy) of the tentative minefield.
He paces off the distance and records it in meters. This point (Bl) marks the
beginning of the second row. The leader places a marker at Bl and records the
azimuth and the distance on DA Form 1355- 1-R.

Row Mining 6-35

FM 20-32

Mine Removal

From Bl, the leader measures the azimuth and distance to a second point on
the right side of the minefield (facing the enemy). He places a marker at this
point (Al), and records the information.

The leader measures the distance and the azimuth from Al to the location of
the first mine in that row. The distance (or spacing) from the end row marker
to the first mine is the mine spacing for that row. After the leader records the
location, the mine is emplaced, but it is not armed.

The distance and azimuth are measured from the first mine to the second
mine, and so on, until all the mines are emplaced and the locations are
recorded. This procedure is repeated for the second row. As each mine is
recorded, it is assigned a number to identify it in the minefield record.

When the last mine location is recorded for a row, the distance and the
azimuth are measured from that point to another arbitrary point, A2 or B2. A
marker is placed here in the same manner as Al and Bl. Next, the distance
and azimuth from the RP toB2 and from B2 toA2 are measured and recorded.

When all the mines have been placed and recorded, the leader measures the
distance and the azimuth between the RP and a permanent landmark that
can be found on the map. He records the information on DA Form 1355-1-R.
The landmark is used to assist others in locating the minefield if it is
transferred or unexpectedly abandoned.

M ines can be armed after recording is complete. M ines nearest the enemy are
armed first, allowing soldiers to safely work their way back to the unit
position. Pins and clips are buried 30 centimeters behind row markers, theRP,
or any easily identifiable, accessible location. Record the location of the pins
and clips in the remarks section of DA Form 1355-1-R. The leader then reports
the completion of the minefield to higher headquarters.

If the minefield is transferred to another unit, the transferring unit leader
briefs the gaining unit leader. The gaining unit leader signs and dates the
mines-transferred block on the DA Form 1355-1-R. The form is destroyed
when the minefield is removed. If the minefield is abandoned unexpectedly,
the DA Form 1355-1-R is forwarded to higher headquarters.

When removing mines from a hasty protective row minefield, the leader first
determines the best method to use:

• If the minefield has been under constant observation from the time it
was laid and has not been tampered with, the squad leader directs the
personnel who laid the mines to pick up the same mines. He uses DA
Form 1355-1-R preceded by a mine detector to determine the types of
mines to be removed and where they are located.

• If the minefield has not been under constant observation, may have
been tampered with, or the personnel who laid the mines are not
available or do not remember the location of the mines, the squad
leader uses DA Form 1355-1-R and a clearance team as outlined in
Chapter 11 to locate and remove mines.

6-36 Row Mining

C2, FM 20-32

The leader retrieves safety devices, shipping plugs, and other items that
accompanied the emplaced mines. Using the azimuths and distances provided
on the DA Form 1355-1-R, the removal team starts at the RP and moves to Bl.
They then move from Bl to the mine and remove the mine. If Bl is destroyed,
the team moves from the RP to B2. The team then shoots a back azimuth
(subtract 180 degrees) from the recorded azimuth from B2 to the first mine
and removes the mine. Personnel continue this process until all the mines
have been removed. The stakes at Al, Bl, A2, and B2 are necessary because it
is safer to find a stake than to find an armed mine.

The removal team observes basic safety precautions by maintaining 30 meters
between personnel, not running, and moving only in cleared areas. Theteam
starts with the row closest to the defender and works toward the enemy.
Personnel—

• Check the sides and bottoms of the mines for AHDs, and disarm or
mark the mines as they are found.

• Replace all pins, clips, and other safety devices before the mines are
removed from the ground.

• Turn arming dials to SAFE or UNARMED; or if mines have screw-
type fuses, remove the fuses and take them away from the mines.

• Lift the mines from the holes after they have been rendered safe.

— If a mine was put in place and kept in sight by the individual who
removes it, he lifts it directly from the hole after rendering it safe.

— If a mine has not been kept in sight, the individual attaches a
60-meter rope or wire to the mine, takes cover, and pullsthemine
from the hole.

• As each mine is removed, place a tick mark beside it on the DA Form
1355-1-R.

• Assemble all the mines in one location for accountability.

NOTE: AHDs are not used in hasty protective row minefields.
However, as a safety precaution, consider all mines to be equipped
with AHDs until proven otherwise.

The leader confirms the removal of the mines and accounts for the number of
mines, by type, as recorded on the DA Form 1355-1-R. The leader may find it
necessary to confirm an exploded mine to account for all the mines.

To confirm a mine explosion that was not witnessed, identify the crater or
traces of burnt soil made by the detonated mine and place a tick mark beside
the mine number on the DA Form 1355-1-R. Ensure that the crater found in
the vicinity of the mine was caused by a land mine and not by artillery. A mine
crater is normally circular, and it shows traces of burnt soil. The impact and
thesoil dispersion of artillery is normally elongated.

The squad leader confirms that each mine is disarmed and safe. The removal
team cleans and repacks serviceable mines for future use and destroys the
others; they repack serviceable mines in their original containers and store
them according to the unit SOP and local regulations. The removal team

Row Mining 6-37

FM 20-32

removes and stores the row markers. The leader submits a report to his higher
headquarters stating that the minefield has been removed and that the area
is clear.

6-38 Row Mining

This chapter implements STANAG 2036.

Chapter 7

Standard-Pattern Minefields

Emplacing standard-pattern minefields is laborious and time-consuming,
but it allows better mine concealment than row mining. Standard-pattern
laying is well suited for protective and nuisance minefields. It can be used
in terrain where the nature of the ground makes row mining
impracticable.

To achieve their maximum effect, mines must belaid so that they cannot
be seen and so that a vehicle's wheel or track or a person's foot exerts
enough pressure to detonate them.

The method used to lay mines depends on the mine operation, the type of
ground in which the mine is to be laid, and the type of ground cover that is
avai I abl e for camouf I age.

COMPONENTS

Mine Strips

Mine Clusters

The mine strip is the foundation of a standard-pattern minefield. If a mine
strip was laid in one straight line, the enemy could easily locate the mines;
therefore, mine strips are laid in several segments as shown in Figure 7-1,
page 7-2.

When siting, laying, and recording mine strips, all measurements are
expressed in meters. Directions are recorded as magnetic azimuths, in
degrees.

The cluster is the basic unit of a minefield. It consists of one to five mines that
are laid within a 2-meter-radius semicircle (Figure 7-2, page 7-3). When
clusters are placed in a mine strip, they are numbered progressively and may
consist of—

• One AT mine.

• Korea Only: One AT mine and onetofour AP mines.

• Korea Only: One to five AP mines.

Standard-Pattern Minefields 7-1

FM 20-32

End points of
mine strip

Cj ^J ^

Strip segment

K ~' V_7 PS r--L I

C2

Figure 7-1. Minefield layout

Clusters are placed at 6-meter intervals, center to center, to form rows. Two
parallel rows, 6 meters apart, form a mine strip. The arrangement of clusters
in a mine strip is shown in Figure 7-3.

Rules for Positioning Clusters Within a Strip

The first cluster is placed on the enemy side of the strip centerline, 6 meters
from the beginning-of-strip marker. The following clusters are numbered
consecutively. Odd-numbered clusters are always on the enemy side of the

7-2 Standard-Pattern Minefields

FM 20-32

Individual laying of AT mine (to
be at base of cluster)

•

Korea Only: Cluster with one
AT mine plus several AP mines
within or on a 2-meter semicir-
cle of the AT mine (the AT mine
must be the base mine)

i_ w a i

Korea Only: Individual laying
of AP mine (to be at base of
cluster)

w

Korea Only: Cluster with sev-
eral AP mines within or on a 2-
meter semicircle of the center
AP mine (the most easily
detected mine is the base
mine)

Figure 7-2. Cluster compositions

Centerline

ENEMY

3 m

t

6 m

-0

Beginning-of-
strip marker

Figure 7-3. Arrangement of clusters in a mine strip

strip centerline. The direction of laying follows the numbering (Al toA2, Bl to
B2, and soon).

The IOE is normally the first part of the minefield encountered by the enemy.
It consists of a baseline from which short strips are extended (Figure 7-4, page
7-4). Short strips along the IOE deceive the enemy on the minefield's pattern,
spacing, and size. IOE placement and composition are largely dictated by the

Standard-Pattern Minefields 7-3

FM 20-32

time allowed for laying the minefield, terrain conditions at the laying site, and
the tactical situation.

Figure 7-4. IOE baseline with short strips

The IOE baseline extends from one end point (IOE1) to another end point
(IOE2). The laying direction is indicated by end-of-strip markers. Laying
always begins at I OE1. I nter mediate or turning points are marked in
consecutive order beginning with 1 1. On the enemy side of the IOE baseline,
short strips are extended from turning points at irregular angles. They are
identified by turning-point markers.

Turning points should be no more than 45 degrees from the last azimuth. The
length of short strips is not standard. A marker is emplaced at the end of each
short strip. Markers are numbered in consecutive order beginning with HE
for recording purposes. Notrip wires are used in the IOE, but AHDs may be
employed.

Korea Only: AP mines actuated by trip wires are placed on the enemy
side of each regular strip. No more than one mine per cluster uses
trip wires, and no more than two trip wires extend from the mine.
Trip wires are angled toward the enemy and should be at least 2
meters from the cluster, the lane border, and the minefield boundary.
Trip wires are only used with AP fragmentation mines; they are not
considered to be AHDs.

Standard-Pattern Minefield Rules

Clusters

The following rules apply to tactical and protective standard-pattern
minefields. They do not apply to nuisance minefields.

A cluster is a 2-meter-radius semicircle located 3 meters off the strip
centerline.

There are two types of clusters— live and omitted.

7-4 Standard-Pattern Minefields

Regular Strips

FM 20-32

— A live cluster contains one AT mine. (Korea Only: A live cluster
contains as many as five mines, only one can be an AT
mine).

— Omitted clusters do not contain mines, but they are numbered and
recorded on DA Form 1355 (see Chapter 8).

Clusters are omitted within lanes and gaps; in areas less than 2
meters from boundaries, lanes, or another cluster (including the I OE);
and in areas where the terrain (trees, rocks) prohibits emplacement.

The base mine in a live cluster is the first mine laid. It is 3 meters
from the strip centerline.

When a live cluster contains an AT mine, the mine is always used as
the base mine. (Korea Only: If an AT mine is not present, the
largest metallic AP mine is the base mine.)

The first cluster in a mine strip is located on theenemy side, 6 meters
from the beginning-of-strip marker.

The minimum distance between a cluster and a lane, a gap, a
boundary, or another cluster is 2 meters (measured from the edge of
the cluster).

Cluster composition is the number of mines, by type, in any cluster in
a specific group.

Cluster composition remains the same through the entire mine strip
and is recorded on DA Form 1355.

Korea Only: The types of AP mines may vary within a cluster.

The cluster boundary must at least 15 meters from the minefield
perimeter fence.

Clusters are numbered, beginning with the first cluster on theenemy
side. Odd-numbered clusters are always on the enemy side of the
strip, and even-numbered clusters are always on the friendly side.

A regular strip (sometimes referred to as a lettered strip) consists of a
strip centerline and two rows of clusters (Row 1, enemy side; Row 2,
friendly side).

Regular strips are marked and recorded. They are designated by
letters (A, B, and so forth), with Strip A being closest to the enemy.

A standard-pattern minefield contains at least three regular strips.

The minimum distance between strip centerlines is 15 meters; there is
no maximum distance.

Safety tapes are used to ensure that personnel installing trip wires do
not move forward into armed clusters. A safety tape is used behind
each regular strip. Safety tapes are 8 meters from the strip centerline
(3 meters from the outer edge of the cluster).

Standard-Pattern Minefields 7-5

FM 20-32

IOE

IOE Short Strips

The marking of end points indicates the direction of laying (for
example, Al toA2).

The IOE consists of a baseline from which short strips are extended.

The IOE is located on the enemy side of the minefield.

The number of clusters in an IOE is approximately one-third the
number used in a regular strip.

The first cluster along a short strip is placed on the enemy side and
must beat least 6 meters from the IOE baseline; the cluster boundary
must be at least 2 meters from the IOE baseline (Figure 7-5). If the
short strip is exactly parallel to the enemy direction of travel, the
NCOI C designates the enemy side of the strip.

The IOE baseline is labeled at the beginning (IOE1) and end (IOE2)
according to the direction mines areemplaced.

Short strips are labeled at turning points (II) and at the end (HE).

The IOE contains a safety tape that is 2 meters behind the IOE
baseline and runs parallel with it.

The IOE baseline is at least 15 meters from any point of the strip
centerlineof a regular strip; there is no maximum distance.

An IOE short strip is at least 15 meters from another IOE short strip;
there is no maximum distance.

AH Ds may be employed.

Short strips originate from turning points along the IOE baseline.

The number and length of short strips depend on the tactical situation
and the resources available.

Trip Wires (Korea Only)

• Trip wires are not used in an IOE.

Turning Points

Trip wires may be used in regular strips, but only one mine
per cluster may be actuated by a trip wire.

Trip wires are employed no closer than every third cluster.

No more than two trip wires can be used on one mine.

Trip wires are used only on the enemy side of the strip.

Trip wires are not considered AHDs.

Trip wires are located at least 2 meters from a lane, a safety
tape, a cluster, another trip wire, the IOE baseline, and the
minefield perimeter fence.

Trip wires can only be used with AP fragmentation mines.

Clusters must be at least 3 meters from turning points.

7-6 Standard-Pattern Minefields

FM 20-32

Lanes

ENEMY

Figure 7-5. Clusters on an IOE short strip

The first cluster after a turning point is laid on the opposite side of the
strip centerlinefrom the last cluster before the turning point.

The angle of any given turning point cannot exceed 45 degrees from
the last azimuth. (This ensures a minimum distance of 2 meters
between cluster boundaries in the same row.)

Minefield lanes (Figure 7-6, page 7-8) are used by dismounted patrols
and vehicles.

Lanes are sited before laying begins.

Lane locations should not be obvious.

Clusters are not laid within 2 meters of lane edges.

Lanes are zigzagged, not straight.

Lanes cross the strip centerlineat approximately right angles.

Direction changes will not exceed 45 degrees. (This ensures that long
vehicles will beableto negotiate turns.)

The number of lanes must be sufficient to ensure that no one lane is
overused and turned into an obvious track.

Sufficient mines are stockpiled so that the responsible unit can close
lanes suspected of being located by the enemy.

Recommended minefield lane widths are—

— Footpath: 1 meter.

Standard-Pattern Minefields 7-7

FM 20-32

Gaps

General

Figure 7-6. Minefield lanes and gaps

— One-way vehicle lane: 8 meters.

— Two-way vehicle lane: 16 meters.

Minefield gaps (Figure 7-6) are left so that friendly forces can pass
through the minefield in tactical formation.

Gaps must be at least 100 meters wide.

Gaps are sited before laying begins.

Gaps are located along recognizable features (fences, tracks, creeks).

Gaps should run straight through a minefield and not contain bends.

Sufficient mines must be stockpiled so that the responsible unit can
close gaps when necessary.

Gaps should closely resemble the rest of the minefield so that they will
not be discovered by the enemy.

The ground within a gap should be disturbed with tracks to represent
the passage of a mine-carrying vehicle.

Signs of mine laying (digging, scattered spoil, crates) should be visible
in a gap.

The farthest extremities of a regular strip determine the minefield
front.

Minefield depth is measured from the first to the last strip and
includes the I OE (if applicable).

Strips can be laid left to right or right to left.

Back azimuths are not used to record the minefield.

7-8 Standard-Pattern Minefields

FM 20-32

The minefield will have two landmarks located to the rear, never to
the extreme side or front.

GPSs can be used to determine the coordinates for minefield
landmarks and reference points.

WARNING
Do not use GPSs to chart or record minefield perimeter coordinates
or to determine safe routes through or around existing minefields.

• If landmarks are more than 200 meters away from the last regular
strip or are out of the direct line of sight, intermediate markers are
placed at least 75 meters from the last end-of-strip marker.

• Landmarks can be used for more than one minefield. They are
recorded on DA Form 1355.

LOGISTICAL CALCULATIONS

E mplacing standard-pattern minefields allows the unit to calculate the
number of mines required for a minefield accurately.

To simplify the calculation process, a minefield requirements computation
work sheet (Figure 6-1, pages 6-5 through 6-8) has been developed. Step-by-
step procedures for completing the work sheet are shown in Figure 6-2, pages
6-9 through 6-14.

Cluster Calculation

Accuracy is essential when emplacing a standard-pattern minefield. The
following check system has been designed so that the minefield 01 C can
accurately record the number of mines laid. Compare the strip feeder report
with the—

• Number of pins and clips returned by the laying party.

• Mine tally sheet.

• Cluster computation.

EXAMPLE: You receive a strip feeder report for Strip A. There are 26
clusters in the strip. The strip has three segments (30, 42, and 21 meters) and
two turning points.

Step 1. Add the total length of the strip as determined by the recording party.

30 +42 +21 =93 meters

Step 2. The first and last cluster in the strip are located 6 meters in from the
end-of-strip markers. Subtract 12 from Step 1.

93 - 12 = 81 meters

Step 3. Clusters are not located on turning points. Multiply the number of
turning points by 3 and subtract it from Step 2.

81 -(3x2) =75 meters

Step 4. Divide Step 3 by the cluster spacing.

75 +3 =25 clusters

Step 5. Add one cluster, because when a line is divided, there is one more
interval than spacing.

25+1 =26 clusters

Standard-Pattern Minefields 7-9

FM 20-32

F rom these computations, the minefield 01 C is able to cross-check the
information on the strip feeder report. In this example, Strip A should have a
total of 26 clusters, less any omitted clusters.

Platoon Organization

The platoon is the basic unit used to install a standard-pattern minefield.
Orders to the laying unit OIC specify the proposed location, the length, and
the mine type and density. The platoon organization and equipment are
shown in Table 7-1.

Table 7-1. Platoon organization and equipment

Personnel

Officer

NCO

EM

Equipment

Supervisory

1

1

Officer: Map, lensatic compass,
notebook, and minefield record
forms

NCO: Map, lensatic compass, and
notebook

Siting party

1

3

Stakes or pickets,
sledgehammers, engineer tape on
reels, and nails to peg tape

Marking party

1

2

Rolls of barbwire or concertina,
marking signs, lane signs, wire
cutters, gloves, sledgehammers,
pickets, and picket pounder

Recording
party

1

2

Sketching equipment, lensatic
compass, minefield record forms,
map, and metric tape

First laying
party

1

6-8

Notebook for squad leader, picks,
shovels, and sandbags

Second laying
party

1

6-8

Same as first laying party

Third laying
party

1

6-8

Same as first laying party

Totals

1

7

25-31

Siting Party

The Ol C performs a map study, and if the situation permits, conducts a
ground reconnaissance of the site. He determines locations for mine strips,
landmarks, fences, mine dumps, and approaches. Using the minefield
requirements computation work sheet (Figure 6-1, pages 6-5 through 6-8), the
OIC determines the required number of mines and other materials. He
arranges for mines to be delivered and organizes the platoon into siting,
laying, recording, marking, and mine-dump parties.

The siting party places boundary stakes or pickets as strip markers at the
beginning and end of each mine strip and at the points where strips change
direction. It lays tape on thecenterlines of each strip, lane, and traffic path.
After siting is complete, the siting party augments other parties.

7-10 Standard-Pattern Minefields

Laying Parties

FM 20-32

One laying party is responsible for installing, arming, and camouflaging all
the mines on a strip or a portion of a strip. Each laying party is then assigned
additional strips.

Recording Party

The recording party obtains the necessary reference data, prepares DA Form
1355 (see Chapter 8), and when needed, installs intermediate markers.

Marking Party

The marking party erects fences and signs to mark minefield boundaries and
lanes. After marking is complete, the marking party augments other parties.

Mine-Dump Party

The mine-dump party, controlled by the PSG, is composed of personnel who
are not working as members of other teams. It accounts for all Class IV and V
supplies that arrive from other sources, organizes mine sets at the mine
dump, and hauls additional supplies as required. The PSG is not required to
stay at the mine dump continuously; he has the flexibility to move around the
area to perform other activities.

Mine-Emplacement Procedures

Mine-emplacement procedures are shown in Figure 7-7. I n the illustration,
the minefield is laid from right to left.

Figure 7-7. Mine-emplacement procedures

Standard-Pattern Minefields 7-11

FM 20-32

The 01 C arrives at the site with the siting and marking parties. He goes to the
right or left (depending on the laying direction) rear boundary of the
minefield. This part of the minefield is the farthest from the enemy. The 01 C
indicates the starting point of the rear strip (this is Strip C in a three-strip
minefield), and the siting party empl aces a beginning-of-strip marker.

The 01 C designates a starting point for the marking party that is at least 15
meters to the right of the boundary stake. He indicates where the minefield
marking fence should be placed. The marking party immediately begins to
install fence pickets, working in a counterclockwise direction.

When all the pickets are installed, the marking party encircles the field with a
single strand of barbwire (at waist height) and emplaces mine signs.
Personnel empl ace a second strand of barbwire if required.

From the boundary stake of Strip C, the 01 C moves in the direction of the
enemy and establishes the starting point of Strip B. Strip centerlines should
not be parallel nor less than 15 meters apart. Two members of the siting party
emplace a beginning-of-strip marker at the starting point of Strip B. The
remaining two members lay tape between the two strips and fasten the tape to
the ground at frequent intervals to prevent movement. This procedure is
followed until the beginning-of-strip markers of the three regular strips (C, B,
and A) and the IOE on the right-hand side of the minefield have been
installed.

At the IOE beginning-of-strip marker (I0E1), the 01 C gives the siting party a
sketch of the minefield and instructions on siting the IOE baseline and strip
centerlines. The NCOIC and one other member of the siting party
immediately begin setting stakes to indicatethe IOE baseline. Thecenterline
laying team lays tape on the IOE baseline, leaving tape reels where tapes run
out. Short strips extending from the IOE baseline are established at the same
time. Each short strip starts with a marker that is designated as II, 12, and so
forth and ends with a marker that is designated as I IE , 1 2E , and so forth.
Turning points are not used on short strips.

Upon reaching the IOE end-of-strip marker (IOE 2), the NCO moves away
from the enemy side, establishes the left boundary stake of Strip A, stakes out
Strip A, and repeats the procedure until all strip centerlines are taped. All
stakes are driven flush with the ground.

While the IOE is being taped, the recording party obtains reference data for
the DA Form 1355. Working behind the siting party, the recording party
starts from Landmark 1 (designated by the 01 C) and proceeds to CI. After C2
has been sited, the recording party proceeds from Landmark 2 to C2 to
establish the distance and the azimuth. Finally, the recording party ties CI
and C2 to both landmarks in case one of the landmarks is removed or
destroyed. The amount of detail obtained by the recording party depends on
the tactical classification of the minefield and any special orders. Aerial
photographs taken of the minefield before the tracing tape is removed become
valuable supplements to the DA Form 1355.

As soon as laying parties arrive at the site with mines, they establish mine
dumps a minimum of 150 meters apart and 50 meters behind the field. They
uncrate and stack AT mines and place fuses and detonators in separate boxes.

7-12 Standard-Pattern Minefields

FM 20-32

Fuse types are not mixed. (Korea Only: AP mines are left in their crates,
and the crate lids are removed.)

When the siting party completes the centerline staking, it installs lane tapes
and traffic tapes, respectively. Lane tapes are used by tactical vehicles and
patrols. Traffic tapes are used by laying personnel to assist in camouflage and
to reduce the amount of traffic on strip centerlines. Traffic tapes are laid
perpendicular tothe minefield trace at 100-meter intervals.

Mine Emplacement

The laying party must know the cluster composition of the strip, the location
of any omitted cluster, and future lane locations. When the centerline tape for
a regular strip has been installed, theNCOIC designates all but two members
of the laying party to emplace mines in the ground. The remaining two
soldiers, usually the most experienced, are designated as fusers and are
responsible for arming mines. Layers carry the maximum load of mines to be
used as base mines in the clusters. Fusers carry thefuses and the detonators.

The NCOIC moves to the right or left (depending on the laying direction)
beginning-of-strip marker of the strip and organizes the layers into one
column to his rear, directly on the centerline. He measures 6 meters along the
centerline for the first cluster and, pointing perpendicular from thecenterline
and in the direction of the enemy, indicates the placement of the base mine.
The first layer on the enemy side places a mine on the ground, 3 meters from
thecenterline.

The NCO measures 3 more meters and indicates the placement of the second
base mi neon the opposite (friendly) side of the strip. The first layer on that
side places a base mi neon the ground. As the initial load of mines is laid, each
layer returns to the nearest mine dump for another load. Fusers follow behind
layers and insert minefuses, but they do not arm the mines. This procedure is
followed until the end-of-strip marker on the far side of the minefield is
reached.

Korea Only: The NCO tells layers the number and type of mines to be
placed next to the base mine in each cluster. As AP mines are being
placed, the NCO proceeds along the strip and ensures that the proper
number of AP mines is placed in each cluster. The NCO places a spool
of trip wire next to the mines that are to be activated by trip wire.

When all the mines are positioned in clusters, one layer is assigned to dig the
holes for all the mines in a cluster. He places the spoil from the holes in
sandbags and leaves the sandbags beside the base mine in each cluster. The
layer checks the positioning of the mines in the holes, removes the mines from
the holes, and places the mines beside the holes. (Korea Only: The layers
anchor trip wires with nails or stakes and wrap the loose ends of trip
wires around the fuses.)

When digging has progressed at least 25 meters from the first mine laid, the
arming procedure begins. Fusers arm all the mines in a cluster, beginning
with the mine farthest from the centerline and work backward. They place all
the mines in the holes (Korea Only: attach trip wires) and arm and
camouflage the mines. They place filled sandbags on the centerline of the

Standard-Pattern Minefields 7-13

C2, FM 20-32

strip, opposite the base mine. F users keep their back toward thecenterline.
Other personnel must remain at least 25 meters from the fusers (Figure 7-8).

Boundary
stake

6 m

Q

Q

Enemy

Q

Q

NCOIC

Fuser

3 m

6

Tape

25 m (minimum)

Enemy
Layer Layer

\ 5g

6 m

3 m

NCOIC

Boundary
Fuser stake

Tape

Layer

Layer

Layer

Figure 7-8. Laying and fusing mines

M ines located in lanes are not initially buried. They are placed aside to
prevent confusion when counting clusters. The mines can be buried after the
lane is closed. Upon completing the arming operation, fusers give the safety
clips to the NCO, who verifies that all the mines have been armed and
camouflaged. The NCO checks the strip and ensures that sandbags, tape, and
debris have been picked up. The NCO gives the safety clips to the PSG, who
buries them 30 centimeters to the rear of the beginning-of -strip marker.

All mines and other explosive items are recorded upon issue. They are
summarized on a mines tally sheet (see Table 7-2). If more than one mine

7-14 Standard-Pattern Minefields

FM 20-32

dump is established, a mines tally sheet is kept at each dump and the
information is later transferred to a master tally sheet.

Table 7-2. Sample mines tally sheet

Strip/Laying
Party

Movement of
Mines

M15

M16

Trip Wire

AHD Type

IOE strip/
Party 1

No forecasted

23

46

—

—

No issued

23

46

—

—

No returned

—

—

—

—

No used

23

46

—

—

Strip A/
Party 2

No forecasted

81

154

35

—

No issued

81

154

35

—

No returned

7

6

9

—

No used

74

148

26

—

Strips B, C, D,
and so forth

No forecasted

No issued

No returned

No used

Total

No forecasted

No issued

No returned

No used

Date Ra

nk Name

Signature

The PSG ensures that the number of mines used per tally sheet is entered on
the DA Form 1355.

When a lane is no longer required through a minefield, it is closed by a lane-
closure team that consists of one NCO and two other soldiers. Before closure
starts, the NCO checks the minefield record to ascertain the—

• Width of the lane.

• Cluster composition of each strip.

• Total number of mines required.

• Number of strips that intersect the lane.

• Azi muth of each stri p.

• Distance between strips, along the lane centerline.

• Location of the mine dump.

The procedures for lane closure is as follows (see Figure 7-9, page 7-16):

• The lane-closure team moves along the safe-lane centerline until it
arrives at the strip safe-lane marking picket.

• The NCO lays out a strip centerline tape and a tape along both sides of
the safe lane to mark its boundaries.

• The team lays clusters.

• The team recovers the tapes.

Standard-Pattern Minefields 7-15

FM 20-32

The above steps are repeated at successive strips.
The NCO amends the DA Form 1355.

V

/ \

""" ^^

/

/

N, K

K

Strip/safe-lane

4'

marking picket

y \

\

v<2> /

y

\

Engineer tape
- — (safe lane)

/ >

^X

jy'

v' \.

/

jy

v' /

yy'

/ /

\^

Fnginppr tapp

■•/ /

yy*

(strip centerline)

■y /

>£'

\

/ / /

Figure 7-9. Lane closure

NOTE : When gaps must be closed, fences are temporarily erected
along the side boundaries. They are removed later to avoid the
indication of a passage through the minefield.

NCOICsdo not act as working members of their parties; they ensure that—

• No one moves back into a mined area.

• Any irregularity, such as an omitted cluster, is recorded.

7-16 Standard-Pattern Minefields

FM 20-32

• All safety devices are recovered and checked against the minefield
record.

Safety tapes are used to create a network of safe routes through a minefield.
They may be removed progressively but are normally left in place until the
minefield is complete.

Korea Only: When trip wires are used, safety tapes are laid between
strips where the trip wire will be positioned (including Strip A and
the IOE baseline). If trip wires are not used, safety tapes are
recommended but are not mandatory.

NUISANCE MINEFIELDS

Siting

Location

Consider the following factors when siting a nuisance minefield:

• The effort needed by the enemy to bypass a mined area.

• The importance of an area or a route to the enemy.

• Achievement of the goal (use the minimum amount of effort needed to
maximize casualties and the effect on enemy morale).

Remember, the more ingenuous the methods of concealment, the longer it will
take to lay mines.

Observation and covering fires are not essential and are seldom feasible for
nuisance minefields. Their value depends on effective siting and concealment
to cause surprise.

The minefield 01 C is responsible for detailed siting and the design of a
nuisance minefield. He must consider the minefield from the enemy's point of
view and assess the courses open to the enemy when he encounters it. Such
considerations may expose weaknesses in the initial plan and bring about a
change to the proposed minefield layout or may lead to a decision to site the
minefield elsewhere.

I n wooded or hilly terrain, the enemy's logistics transport will normally be
confined to existing routes. Nuisance mines at selected sites along roads can
impose considerable delay on the enemy and have a cumulative effect on his
resources and morale. The best sites for axial mining are-
Natural defiles and constructed areas that are difficult to bypass
(cuts, embankments, causeways, fords, forest tracks, built-up areas).

In the vicinity of road craters, AT ditches, and any obstacles that have
to be cleared.

Around culverts.

Demolished bridges, particularly the home bank, including likely
adjacent crossing places and alternative building sites.

Likely assembly areas.

Covered approaches or dead space.

Standard-Pattern Minefields 7-17

FM 20-32

Laying

In the vicinity of enemy-needed fuel, supplies, and engineering
materials that cannot be destroyed or removed.

Railroads (in or near culverts, bridges, sharp turns, tunnels, steep
grades). Mines should be laid where enemy trains cannot bypass the
mined area on branches or spurs.

There is no requirement for recording the precise location of individual
nuisance mines. Recording mine positions that are laid to a pattern is easy
and quick. Pattern laying should be used when it can be done without
prejudicing concealment.

When the number of mines to be laid on the site makes it impracticable or
undesirable to lay mines in a pattern, they may be scatter-laid unless
otherwise directed. Scatter-laying by hand is useful in road blocks, bridge
abutments, and craters when it would bedifficult and wasteful to lay mines in
a pattern. Again, scatter-laying along routes to be denied to the enemy will
add considerably to the delay imposed. All available types of AT mines
(Korea Only: and AP mines) are used to make nuisance minefields complex
and difficult to remove. Combinations of mine types should be varied
constantly sothat each minefield presents a clearance problem. Deeply buried
mines can be included; however, they take much longer to lay. These mines
may be worthwhile around craters, where the enemy is likely to need
earthmovi ng equi pment.

If a nuisance minefield is laid in a standard pattern, standard procedures are
followed. If mines are selectively positioned, procedures must be tailored to
suit the situation. In all occasions, however, the following rules should be
observed:

• The intended position for each mine is clearly marked on the ground
before laying begins.

• Laying parties work in pairs, and each pair is detailed to lay specific
mines.

Inspection and Maintenance

M ines that are left in the ground for an extended period of time may
deteriorate and malfunction for one or more of the following reasons:

• Moisture may have entered the igniter or body of the mine and either
neutralized the explosive or corroded the metal parts. Such actions
may be aggravated by local factors (soil acidity, wide temperature
swings).

• Frost or heat may have subjected the mine to mechanical strain and
caused distortion.

I nsects or vegetation may have caused obstructions.

• Animals may have turned mines over or detonated them.

Technical inspections should only be made by experienced engineers or EOD
personnel. When a minefield deteriorates below the operating level, additional
mine strips and/or rows must be added to restore its effectiveness. They are

7-18 Standard-Pattern Minefields

FM 20-32

Handover

sited to the front or rear of the existing minefield to increase its depth. New
mine strips and/or rows are treated as a separate, additional minefield.

Technical inspections of minefields are normally done at three-month
intervals, and personnel work in pairs. They are done more frequently during
extreme weather conditions.

Minefield handover is an extremely important task. The following items need
to be addressed between emplacing and overwatching units:

Discussing minefield compositions.

Discussing the minefield configuration and walking and/or riding the
minefield trace.

Discussing lane closure, if applicable.

Training the unit on how to the close lane, if applicable.

Discussing obstacle protection against enemy dismounted patrols.

Signing over the written report (Figure 2-26, page 2-54).

Discussing indirect fires.

Reporting completion of handover to higher headquarters.

Forwarding a copy of the written report and the DA Form 1355 to
higher headquarters.

Standard-Pattern Minefields 7-19

FM 20-32

7-20 Standard-Pattern Minefields

This chapter implements STANAG 2036.

Chapter 8

Reporting and Recording

Reporting and recording mine and minefield/munition field information is
critical to the success of a unit's mission. It not only provides tactical data
for the commander, but it also provides force- protect ion information to
subordinate and adjacent units.

MINEFIELD/MUNITION FIELD REPORTS

A minefield/munition field report is an oral, electronic, or written
communication that concerns friendly or enemy mining activities. The report
format is specified by the local command. It is submitted by the emplacing
unit commander through operational channels to the G3/S3 of the authorized
headquarters. The headquarters integrates the report with terrain
intelligence and disseminates it along with tactical intelligence. The report is
sent by the fastest, most secure means available. Figure 8-1, page 8-2,
summarizes the minefield/munition field report flow at the division level and
below.

Report of Intention

When planning to emplace a minefield/munition field, the unit must submit a
report of intention to notify their higher headquarters. The report doubles as a
request when it is initiated at levels below emplacement authority. The report
includes—

Tactical purpose of the minefield/munition field.

Estimated number and type of mines to beemplaced.

Location.

Proposed start and completion times.

Type of minefield/munition field.

Whether mines are surface-laid or buried.

Whether AH Ds are used.

Location and width of lanes and gaps.

Conventional minefields/munition fields that are part of an OPLAN or a
general defense plan (GDP) approved by the authorizing commander do not
require a report of intention because inclusion in an OPLAN or a GDP implies
an intention to lay.

Report of Initiation

A report of initiation is mandatory. It informs higher headquarters that
emplacement has begun and that the area is no longer safe for friendly
movement and maneuver. The report specifies the time emplacement began

Reporting and Recording 8-1

FM 20-32

<&,

Division
G3

-*

I

k

1
1

Engineer
battalion

1

>

k

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S3

'Brigade^™'"
engineer/

\

Adjacent
brigade

^^

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k

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TF

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company

1

yk*

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w

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[Maneuver
j company

(Maneuver
j company

IManeuver
|company

S

Dordination

- i

Record
Critical c

-*- (

Figure 8-1. Conventional minefield/munition field reporting chain

and identifies the location and the target number of minefields/munition
fields.

Report of Completion

A report of completion is usually an oral report to the authorizing commander.
It indicates that the minefield/munition field is complete and functional. A
report of completion is immediately followed by a completed DA Form 1355 or
1355-1-R.

Report of Transfer

Minefield/munition field responsibility is transferred from one commander to
another in a report of transfer (Figure 2-26, page 2-54). This report is signed
by the transferring and receiving commanders. It includes a certificate stating
that the receiving commander was shown or otherwise informed of all the
mines within the transferring commander's zone of responsibility. The report
states that the receiving commander assumes responsibility for those mines.

8-2 Reporting and Recording

FM 20-32

The report of transfer is sent to the next higher commander who has authority
over the transferring and receiving commanders.

Report of Change

A report of change is made immediately upon any change or alteration to a
previously reported minefield/munition field. It is sent to the next higher
commander and through channels to the headquarters that keeps the written
minefield/munition field record. A report of change is made by the commander
responsible for surveillance and maintenance of the minefield/munition field.

Progress Reports

During the emplacing process, the commander may require periodic reports
on the amount of work completed.

MINEFIELD/MUNITION FIELD RECORDS

Most conventional minefields/munition fields are recorded on DA Form 1355;
hasty protective row minefields/munition fields are recorded on DA Form
1355-1-R.

The laying unit prepares the minefield/munition field record. The 01 C signs
the form and forwards it to the next higher command as soon as possible.
Once the information is entered on the form, the form is classified SECRET,
NATO SECRET, or SECRET-ROKUS. (When used for training, the record is
marked SAMPLE.) The number of copies prepared depends on the type of
minefield/munition field emplaced and the local procedures. Unit SOPs should
provide advanced guidance on how minefield/munition field information is to
be passed to higher, lower, and adjacent commands. Minefield/munition field
records are circulated on a need-to-know basis. Large minefields/munition
fields are recorded on two or more DA Forms 1355.

Once the minefield/munition field is removed, the date of removal, the time
removal was complete, and the name of the unit that removed the minefield/
munition field will be placed in the remarks block of the form. The form will
then be forwarded to the unit's central control cell for mine clearance
information. The central control cell will retain the form for two years and
then destroy it.

When changes are made to an existing minefield/munition field, a new record
must be prepared. This record is marked REVISED. It shows the minefield/
munition field as it is after changes. The original minefield/munition field
number remains unchanged. Some changes which require a new record are-
Relocation of mines in safe lanes.
Relocation of safe lanes.
Changed lane or minefield/munition field marking.

Inclusion of the minefield/munition field into a larger minefield/
munition field system.

Removal or detonation of mines.

Addition of mines tothe minefield/munition field.

Conventional minefield/munition field records are forwarded through
operational channels to theater army headquarters (TAHQ) where they will
be maintained on file by the theater engineer. If a TAHQ has not been
established, minefield/munition field records are maintained on file with the
assistant corps engineer of the AO where the minefield/munition field is
located.

Reporting and Recording 8-3

FM 20-32

Minefield Record

DA Form 1355 consists of a single sheet that is printed on both sides and
folded in half. The front side contains blocks of tabular data, the inside is a
graph of 1-centimeter squares for a scaled sketch of the field, and the back
side includes a computation formula and instructions. The scale for plotting
minefields/munition fields depends on the size of the field. To avoid using two
sheets for the sketch, adjust the scale so that one form will support the sketch.
For very large minefields/munition fields, two sheets may be required. The
system of measurement and the scale size must be indicated in the legend
block. A second form may be used to support any additional information in the
notes block. Any blocks or lines not used on the form must be crossed out to
avoid unauthorized entries on the form.

An exampleof a completed DA Form 1355 is shown in Figures 8-2a through 8-2c,
pages 8-5 through 8-7.

The following step-by-step instructions are provided for completing DA Form
1355:

Block 1. Enter complete data on the laying authority and the laying unit. The
01 C block should include rank, name, and social security number (SSN).

1

AUTHOR.TY: ^ £,d ,^ ^

" mmi \C V^ £*A ^ »*&<

Of FICER IN CHARGE: , x , r> \\ r -I / 1 ^, 1 1 ' 1

Block 2. Enter the date-time group (DTG) for start and completion times. The
recorder block includes rank, name, and SSN.

DATE
AND
TIME

START

oQcL^o-Z

CiftM

3o

COMPLETION

o^OOZ jm,4 SO

RECORDER:

SCC P. LimL, SSo-71-\ft2

Block 3. E nter the copy and the sheet number. The number of copies
prepared depends on the unit SOP and the minefield/munition field
classification.

Copy No.

Sheet No

.of.

NOTE : The minefield/munition field record is forwarded by the
laying unit. One copy is retained by the overwatching unit, one copy
by the next higher command, one copy by the unit central control cell
(for mine clearance information), and one copy by the proper
national territorial authority.

8-4 Reporting and Recording

C2, FM 20-32

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Reporting and Recording 8-5

FM 20-32

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8-6 Reporting and Recording

FM 20-32

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Reporting and Recording 8-7

FM 20-32

Block 4. The minefield/munition field obstacle numbering system (Table 8-1)
consists of 11 characters and 1 obstacle status symbol. It shows the type of
obstacle, the belt and the zone in which it is located, and the headquarters
that established the zone. Abbreviations for obstacle types are shown in Table
8-2.

Unit's name and type
1st Armor Division

Obstacle zone/belt/group
Zone Charlie
Belt 3, Group Delta

Obstacle type and number
Turn minefield/11th obstacle

Obstacle status

Planned

MINEFIELD NUMBER

j.oos"-flAA-S/nl/

Example: Obstacle number 1 005-A2A-SM 21/ indicates that the 5th I nfantry
Division planned the obstacle in Zone A. It is the 21st obstacle in Group A,
Belt 2, and has not been executed. The obstacle is a MOP MS.

Table 8-1. Minefield/munition field obstacle numbering system

Character

Description

1 through 4

Alphanumeric description of the headquarters type and numerical
designation that established the obstacle zone; character 1 designates the
unit type with a letter:

• A = armor division or brigade

I = infantry division or brigade

• C = cavalry division

• R = cavalry regiment

• Z = corps

5

Letter indicating the obstacle zone

6

Number indicating the belt number in the obstacle zone

7

Letter indicating the group in the obstacle belt

8 and 9

Letters indicating the obstacle type (see Table 8-2)

10 and 11

Two numbers indicating the obstacle number in the group

12

One of four characters indicating the obstacle status —

• / = planned obstacle

• — = obstacle being prepared

• + = prepared obstacle (This sign is for reserve demolition targets
and may indicate a readiness state of safe or armed.)

• X = completed obstacle

8-8 Reporting and Recording

C2, FM 20-32

Table 8-2. Abbreviations for obstacle types

B — Bridge Demolition

W— Wire Obstacle

BA

Abutment

WA

Double apron

BS

Span

WB

Booby-trapped

BC

Abutment and span

WF

Tanglefoot

IV

1 — Minefield/Munition Field

WG

General-purpose, barbed tape

MD

Disrupt

WN

Nonstandard

MT

Turn

WR

Road block

MF

Fix

WT

Triple standard

MB

Block

R— Road Crater

MN

Nonstandard

RH

Hasty

MP

Protective

RD

Deliberate

MQ

Nuisance

RM

Mined

MS

Standard pattern

M — Miscellaneous

S — Scatterable Minefield/Munition Field

AD

AT ditch

SA

ADAM

AR

Rubble by CEV gun

SB

Gator

AB

Rubble by blade

SR

RAAM

AT

Abatis

SF

ADAM and RAAM

AE

Rubble by explosives

SM

MOPMS

AM

Movable MOBA obstacle (car, bus)

SV

Volcano

AN

Expedient nonstandard

H-

-Hand-Emplaced Munitions

AL

Log crib, log obstacle

HH

Hornet

AP

Post obstacle (hedgehog, tetrahedron)

HS

SLAM

AH

Log hurdle

B lock 5. E nter the map data as stated on the map(s) used.

MAP. SERIES. NO AND SCALE

H1^4 J- £b coo

SHEET NO (OR NAME)

M-3 2oi5 rtfo^Sfl h\

Block 6. Enter the grid coordinates and a description of at least two
landmarks. If the landmarks are roads, trails, or routes, enter their name or
number. This makes identification easier when removing the minefield/
munition field. When recording minefields/munition fields, GPSs can only be
used to determine the coordinates for minefield/munition field landmarks and
RPs.

WARNING
Do not use GPSs to chart or record minefield/munition field
perimeter coordinates or to determine safe routes through or around
existing minefields/munition fields.

Reporting and Recording 8-9

FM 20-32

6

LANDMARKS

NO

COORDINATES

DESCRIPTION

1

U< 2>4<?i72>i2

(J-£Hflfe^ 9lCK.£f ridSW LJlfM C&U^

2

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X

Lr y^mrb

U- SlKV?£h> ftG<£< £_os* uM4 Cpj^D

*

KlE^-< <d &>Atl

Block 7. Enter the description of intermediate markers, if applicable. When a
landmark is more than 200 meters from the minefield/munition field, or a
strip or row reference stake cannot be seen from the landmark, an
intermediate marker must be used. If possible, the intermediate marker is at
least 75 meters from the stri p or row reference stake.

7

INTERMEDIATE MARKERS

NO

DESCRIPTION

1

3 0-SuaP^ vW^> 12" n&oJ^

Cdou^h

2

— — - > _— -— — — ~~~~~

3

J^rxdC

4

— ■ — ■ ~~~ "~~~~-"-~~~~— - — -.

Block 8. Enter theword STANDARD when a standard marking fence is used.
Describe the boundary marking if a standard marking fence is not used. (Use
two sides and the rear for a tactical minefield/munition field; use four sides for
a protective minefield/munition field.)

DESCRIPTION OF BOUNDARY FENCE OR MARKING SfA/\JkAl? k,

Block 9. Enter the number of strips or rows laid. (Do not include the IOE.)
Describe the strip or row markers. Cross out words that do not apply.

NO. OF STRIPS/H3WS:

DESCRIPTION OF STRIP/0

' M»RKfRS

(J- SWAPffk ?;c^£1S fi_OSH LjI<M CRolML

Block 10. Enter the width, the marking, and the provisions for each lane.
When appropriate, give the types of mines and the number of each type of
mine for closing. (The location of these mines is described in Block 12.)

8-10 Reporting and Recording

C2, FM 20-32

Block 11. Enter the type of minefield/munition field by crossing out the lines
that are not needed. Indicate the method of laying by crossing out incorrect
descriptions. Enter the types of mines and the number of each type of mine.
Also enter the number of AHDs installed in the IOE and in each row. Letter
the strips or rows sequentially, starting with the first one laid. Enter totals.

If the type of munition field is Hornet, enter "Hornet" above the word
"tactical" and line out "nuisance minefield" and "phoney minefield." (See
Figures 8-3a and 8-3b, pages 8-12 and 8-13.)

Reporting and Recording 8-11

FM 20-32

SECRET (when completed)

313TOSBO SI 19 IDT dO NOLLI03

19 BVW 'S9EL WMOd VQ

SMOa Nl
mult KL

5E5KET (when completed)

Figure 8-3a. Sample DA Form 1355 (front side) for a Hornet minefield/munition field

8-12 Reporting and Recording

FM 20-32

a

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scale: 1 cm =_l£LQ_m METRES.
UNLESS OTHERWISE STATED ALL ANGLE
ARE MAGNETIC BEARINGS USING A 360°
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Figure 8-3b. Sample DA Form 1355 (back side) for a Hornet minefield/munition field

Reporting and Recording 8-13

FM 20-32

Block 12. As a minimum, enter the following items in Block 12. Also enter
any additional information that would be useful when removing the minefield/
munition field.

1. M ine clusters at meters spacing.

2. Number of IOE live clusters (all others numbered but omitted).

3a. Number of omitted clusters in the IOE and in regular strips and why
they were omitted.

3b. Omitted clusters in lanes and gaps.

4. Clusters with AHDs (identify the mine and the type of device used).

5. Clusters with trip-wire-actuated AP mines.

6. Strip cluster composition.

7. Location of safety clips and pins (buried 30 centimeters to the rear of
each start strip or row marker).

8. Location of mines for closing lanes and gaps.

9. SD time for special munitions.

12

NOTES

. . 1. MINE CLUSTERS AT . &.. . . METRES/BW SPACING

r 2)/^UM3£^ cf 7c£_ Jj/f cassfEZ^ QkA. eTHtxs ^urt£e®t& far

8-14 Reporting and Recording

FM 20-32

Block 13. Theemplacing unit 01 C signs and dates the form.

13

SIGNATURE (OFFICER IN CHARGE) /j

<

DATE

/o /fart 9o

W

The front side of DA Form 1355 is now complete. Continue on the inside as
follows:

Block 14. When completing the sketch, enter arrows for the direction of the
enemy and the magnetic north. The enemy arrow will always point within the
top 180 degrees of the form; the north arrow will follow one of the graph lines.

14

ENEMY

1

MAGNETIC
NORTH

^ m

Block 15. If a compass was not available, enter what was used in the
information block. Indicate the system of measurement and the scale used.

15

150 azimuth LEGEND

example: indicates

= l£

distance
m METRES.

20
scale: 1 cm
UNLESS OTHERWISE STATED ALL ANGLES
ARE MAGNETIC BEARINGS USING A 360°
COMPASS. INDICATE ALTERNATIVE IF USED.

ALL DISTANCES RECORDED ARE IN METRES
INDICATE SYSTEM OF MEASUREMENT USED

PACING
(0.75M)

CLOTH
100MTAPE

STEEL
100MTAPE

OTHER

/

Reporting and Recording 8-15

FM 20-32

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8-16 Reporting and Recording

C2, FM 20-32

Block 17. Enter the security classification of the form. If the form was used
for training, enter the word SAMPLE.

17 S^OR€T (when completed)

Block 18. Theemplacing unit 01 C signs the signature block.

18

SIGNATURE

y^ e

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Hasty Protective Row Minefield Record

Hasty protective row minefields/munition fields are recorded on DA Form
1355-1-R (Figure 8-4, page 8-18). DA Form 1355-1-R will be printed on 8V2- by
11-inch paper. A copy for local reproduction is available in the back of this FM.
DA Form 1355-1-R is also avail able on theArmy Electronic Library (AEL) CD-
ROM (EM 0001) and the USAPA web site (www.usapa.army.mil).

Use the following formula to determine the scale used on DA Form 1355-1-R:

Distance from RP to the farthest point in the minefield +10 meters +4 = scale

Example: 90 meters + 10 meters = 100 meters +A =25 meters

The number 4 is a constant and represents the four concentric rings on DA
Form 1355-1-R. Ten is added as a safety margin to ensure that the minefield/
munition field sketch is entirely contained within the largest ring. The
distance between rings is 2 centimeters; therefore, the scale used in this
example is 2 centimeters =25 meters.

Reporting and Recording 8-17

C2, FM 20-32

HASTY PROTECTIVE ROW MINEFIELD RECORD

For use of this form, see FM 20-32; the proponent agency is TRADOC.

Azimuth Block

Scale: 2 cm = 25 meters

Tabular Block

Identification Block

Row

Type

Actuation

Mine Number

A

M-15

Pressunt

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Mines Transferred

Time and Date

loo m

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m

50 m

25

m

0m

55 m

5o m

IS m

loo m

Figure 8-4. Sample DA Form 1 355-1 -R

8-18 Reporting and Recording

FM 20-32

The following step-by-step instructions are provided for completing DA Form
1355-1-R (see Figure 8-5):

MASTV enOTlCHVf MIMMIiCj "ICO"0

\ 1

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\ 1 <*. \
"I*

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fel\

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5"o,

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Figure 8-5. Hasty protective row minefield/munition field record

From the RP, the leader measures the magnetic azimuth, in degrees, to a
specific point on the right side (facing the enemy) of the tentative minefield/
munition field. He determines the distance and records it in meters. He
identifies the method of measurement in the remarks block of DA Form 1355-
1-R (for example, distances were paced out and multiplied by 0.75 to convert
the measurement to meters). This point, called Bl (if there are two rows),
marks the beginning of the second row. A marker is placed at Bl, and the
leader records the azimuth and the distance.

The leader measures the azimuth and the distance from Bl to a second point
on the right side of the minefield/munition field (facing the enemy). A marker
is placed at this point and recorded as Al.

The leader measures the distance and the azimuth from Al to the location of
the first mine in that row and records the information.

The distance (or spacing) from the end row marker to the first mine is the
spacing between all the mines in that row. After the location is recorded, the
mine is emplaced, but it is not armed.

The leader measures the distance and the azimuth from the first mine to the
second, and so on, until all the mines are emplaced and their locations are
recorded. This procedure is repeated for the second row. As each mine is
recorded, it is assigned a number to identify it in the minefield/munition field
record. When the last mine location is recorded for a row, the distance and the
azimuth are measured from that point to another arbitrary point, A2 or B2. A
marker is placed here in the same manner as Al and Bl. Next, the distance
and the azimuth from the RP to B2 and from B2 to A2 are measured and
recorded.

Reporting and Recording 8-19

FM 20-32

When all the mines have been emplaced and recorded, the leader measures
the distance and the azimuth between the RP and a permanent landmark
that can be found on the map. He records the information on DA Form 1355-1-
R. The landmark is used to help locate the minefield/munition field if it is
transferred or unexpectedly abandoned. Finally, the tabular and
identification blocks are completed.

Mines can be armed after recording is complete. The mines nearest the enemy
are armed first, allowing soldiers to safely work their way back to the unit's
position. Pins and clips can be buried 30 centimeters behind row markers, the
RP, or any easily identifiable, accessible location. Note the location in the
remarks section of DA Form 1355-1-R. The leader then reports the completion
of the minefield/munition field to higher headquarters.

If the minefield/munition field is transferred to another unit, the receiving
unit leader is briefed by the transferring unit leader. Thereceiving unit leader
signs and dates the mines transferred block on the DA Form 1355-1-R. When
the minefield/munition field is removed, the form is destroyed. If the
minefield/munition field is abandoned unexpectedly, the DA Form 1355-1-R
must be forwarded to higher headquarters.

Nuisance Minefield

It is unnecessary to record the precise location of individual nuisance mines
that are laid in a pattern. Recording the position of a minefield/munition field
that is laid in a pattern (either a standard pattern or one adopted for the
situation) is easy and quick. However, the number of mines to be laid on site
may make it impracticable or undesirable to lay mines in a pattern. In this
case, they may belaid individually and their positions accurately recorded.

Figures 8-6a and 8-6b, pages 8-21 and 8-22 provide an example of a completed
nuisance minefield/munition field record.

SCATTERABLE MINEFIELD/MUNITION FIELD REPORTING AND
RECORDING

The speed and responsiveness of SCATM I NE employment require accurate,
uniform, and timely reports. All known information on scatterable minefields/
munition fields is simply and rapidly reported to all affected units. Although
SCATMINES have SD capability, they are still recorded; and the information
is disseminated to prevent casualties to friendly forces.

Si nee the locations of individual SCATM I NEs are unknown, they cannot be
recorded in detail. For most systems, a safety zone is calculated from one or
more aim points. For example, a RAAM minefield/munition field is recorded
based on the target location (the grid coordinates given to the firing battery).
The size of the minefield/munition field depends on the number of rounds
fired, the number of aim points, and the angle of fire. An artillery-delivered
minefield/munition field is recorded by plotting it on a map, based on the aim
point and the safety zone specified in the scatterable minefield/munition field
report and record that was prepared by theemplacing unit. A ground-Volcano
minefield/munition field can be recorded more accurately by plotting each of
the minefield/munition field corner points rather than an aim point.

8-20 Reporting and Recording

C2, FM 20-32

S.vruii se^ST

3131OS90 SI 19

is dv/g 'ssei

inr jo NoiLim

lAiuod va

'>-WUr tvtestei" (when completed)

Figure 8-6a. Sample DA Form 1355 (front side) for a nuisance minefield/munition field

Reporting and Recording 8-21

FM 20-32

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Figure 8-6b. Sample DA Form 1355 (inside) for a nuisance minefield/munition field

8-22 Reporting and Recording

C2, FM 20-32

To facilitate reporting and recording of scatterable minefields/munition fields,
a simple, uniform procedure is used. This procedure combines the report and
the record into one document (Figure 8-7) that is applicable for all delivery
systems.

Line
No

Information Required

Data

1

Approving authority

Enter the approving authority, such as CDR 3AD.

2

Target/obstacle number

If the minefield/munition field is part of an obstacle plan, enter the
obstacle number, such as 2XXX0157. This number represents II
Corps, target number 157. If the minefield/munition field is not a
part of an obstacle plan or does not have a number, then leave
this line blank or enter NA.

3

Type of emplacing
system

Enter the type system that emplaced the minefield/munition field,
such as artillery or Volcano.

4

Type of mines

Enter AP for antipersonnel mines and AT for antitank mines. If
both types of mines are used, enter AP/AT

5

Life cycle

Enter the DTG the minefield/munition field was emplaced and the
DTG the last mine SDs.

6-14

Aim point/corner points
of minefield/munition
field

If the system used to emplace the minefield/munition field uses a
single aim point to deliver the mines, enter that aim point, such as
MB 1 01 02935. If the system has distinct corner points (Volcano),
enter those corner points, such as MB 1 7954790, MB 1 8604860,
MB 18504890, and MB 18054895.

15

Size of safety zone from
aim point

If an aim point is given in Line 6, enter the size of the safety zone
from that aim point. Example: Artillery emplaces a minefield/
munition field from aim point MB 10102935, and the safety zone
is 1 ,000 x 1 ,000 m. Enter 500 m so that personnel plotting or
receiving the information can plot the coordinates and go 500 m
in each direction from the aim point to plot the safety zone.

16

Unit emplacing mines/
report number

Enter the unit emplacing mines and the report number, such as
BCO 23 ENGR BN 4. Reports should be numbered
consecutively. This would be the fourth minefield/munition field
that B Company has emplaced.

17

Person completing
report

Enter the person's name completing the report, such as SFC
Jones.

18

DTG of report

Enter the DTG of the report, such as 160735ZOCT90.

19

Remarks

Include any other items the reporting unit may feel are important.

Figure 8-7. Scatterable minefield/munition field report and record work sheet

In addition to the scatterable minefield/munition field report and record, the
SCATMI N WARN (a sample is shown in Figure 8-8, page 8-24) notifies
effected units that SCATMINEs will be emplaced. These two reports are the
only reports used with scatterable mines.

A completed scatterable minefield/munition field report and record for an
ADAM/RAAM artillery mission is shown in Figure 8-9, page 8-24. Note that
on line 6, only one grid coordinate is given. It is the aim point used when the
mission was fired. Also note that the 500-meter distance from the aim point
(line 15) designates a safety zone that is 1,000 by 1,000 meters.

Reporting and Recording 8-23

C2, FM 20-32

Line

Message

Alpha

Emplacing system

Bravo

AT (Yes or No)

Charlie

AP (Yes or No)

Delta

4 aim or corner points

Echo

Grid coordinates of aim points/corner
points and size of the safety zone

Foxtrot

DTG of the life cycle

Figure 8-8. Sample SCATMINWARN

Line No

Information Required

Data

1

Approving authority

CDR3AD

2

Target/obstacle number

2XXX0157

3

Type of emplacing system

Artillery

4

Type of mines

AT/AP

5

Life cycle

0816102-082020OCT90

6

Aim point/corner points of minefield/munition field

MB 10102935

7

8

9

10

11

12

13

14

15

Size safety zone from aim point

500 m

16

Unit emplacing mines/report number

2/48 FA/2

17

Person completing report

SFC Hollins

18

DTG of report

061645ZOCT90

19

Remarks

NA

Figure 8-9. Scatterable minefield/munition field report and record
for an ADAM/RAAM artillery mission

8-24 Reporting and Recording

C2, FM 20-32

The SCATMI NWARN provides affected units with the necessary warning to
plan and execute their operations. The information is kept to a minimum to
ensure rapid dissemination. The report may be sent orally, digitally, or hard
copy. It is sent before or immediately after the mines have been emplaced. A
completed SCATMI NWARN for an artillery mission is shown in Figure 8-10.

Line

Message

Alpha

Artillery

Bravo

Yes

Charlie

Yes

Delta

One

Echo

MB 10102935 500 m

Foxtrot

081610Z-081920ZOCT90

Figure 8-10. Sample SCATMINWARN for an artillery mission

MINEFIELD/MUNITION FIELD OVERLAY SYMBOLS

The symbols contained in Figure 8-11, pages 8-26 through 8-30, are extracted
from FM 101-5-1 and are provided for posting mine data on maps and
overlays.

Reporting and Recording 8-25

FM 20-32

Description

Symbol

Minefield/Munition Fields

Korea Only: AP mine

V

AT mine

•

AT mine with AHD

t

Directional mine (arrow points in
direction of main effect)

•---

Mine cluster

L .J

Mine, type unspecified

o

Trip wire

t

u

Control Measures

Zone

CD

Belt

o

Restrictions

CZ3

Figure 8-11 . Minefield/munition field overlay symbols

8-26 Reporting and Recording

FM 20-32

Description

Symbol

Block effect

Turn effect

"^

Disrupt effect

P,

u

Fix effect

Conventional

A planned minefield/munition
field consisting of unspecified
mines

[°_°_°]

A completed minefield/munition
field consisting of unspecified
mines

o o o

Scatterable minefield/munition
field (DTGs used for SD times)

s

o o o

DTG

Conventional AP minefield/
munition field reinforced with
SCATMINEs

+ S

vvv

DTG

Tactical AP row minefield/
munition field (outline drawn to
scale)

^SS^si

Figure 8-11. Minefield/munition field overlay symbols (continued)

Reporting and Recording 8-27

FM 20-32

Description

Symbol

Tactical minefield/munition field
of scatterable AT mines, effective
until 101200Z

< ^012° 0Z J

Completed AT minefield/muni-
tion field (drawn away from the
location and connected by a vec-
tor)

• • •

\

/

Executed Volcano minefield/
munition field (DTG used for SD
time)

V

• • •

\. / 100700Z

Lane in conventionally laid AT
minefield/munition field

• • • w-

^

Gap in conventionally laid AT
minefield/munition field (DTG
opened to DTG closed)

— ^</^/C

100900Z -15-ioooz ^y « A-

• ">

Figure 8-11. Minefield/munition field overlay symbols (continued)

8-28 Reporting and Recording

Description

AT ditch reinforced with AT mines

Symbol

UXO

UXO area

UXO UXO

Nuisance

Nuisance minefield/munition field

Demolished crossroads with nui
sance mines

M

Phony

Phony minefield/munition field

M

M

M

M

M

M

Figure 8-11. Minefield/munition field overlay symbols (continued)

FM 20-32

Reporting and Recording 8-29

FM 20-32

Description

Symbol

Phony minefield/munition field,
fenced

Hornet Symbology

Planned

w

Unarmed

w

Armed

•

w

Expended

w

Armed munition field (DTG used
for SD time)

•

w

DTG

Figure 8-11. Minefield/munition field overlay symbols (continued)

8-30 Reporting and Recording

PART TWO

Counteroperations

This part of the manual provides overall guidance for conducting counteroperations by
US forces. The types of breaching and clearing operations conducted, the tasks
performed, and the equipment required are described in detail. Responsibilities and
planning considerations are outlined for each operation.

Chapter 9

Countermine Operations

Countermine operations are undertaken to breach or clear a minefield. All
the tasks fall under breaching or clearing operations and include
detecting, reporting, reducing, proofing, and marking.

DEFINITIONS

Obstacle

The term obstacle is used often in this chapter because the same breaching
and clearing operations are used for minefields and other obstacles. For the
purpose of this manual, breaching and clearing tactics, techniques, and
procedures (TTP) focus solely on minefields.

Reduction is the act or actions taken against an obstacle that diminishes its
original effect. For example, creating a lane in a minefield would yield a
reduction of the minefield obstacle.

Breaching is the employment of TTP to project combat power to the far side of
an obstacle. It is a synchronized combined arms operation that is under the
control of the maneuver commander.

Area clearance is the total elimination or neutralization of an obstacle or
portions of an obstacle. Clearing operations are not conducted under fire. They
are usually performed by follow-on engineer forces after a breaching operation
or anytime in a friendly AO where an obstacle is a hazard or hinders
movement.

Route Clearance

Route clearance is the removal of mines along preexisting roads and trails.

Mine Neutralization

Mine neutralization occurs when a mine is rendered incapable of firing on
passage of a target. The mine may still be dangerous to handle.

Reduction

Breaching

Area Clearance

Countermine Operations 9-1

C2, FM 20-32

Proofing

Demining

Proofing is done by passing a mine roller or other mine-resistant vehicle
through a lane as the lead vehicle. It verifies that a lane is free of mines.

Demining is the complete removal of all mines and UXO within a geopolitical
boundary after hostilities cease.

BREACHING OPERATIONS

Breaching is a synchronized combined arms operation that is under the
control of the maneuver commander. FM 3-34.2 provides combined arms
commanders and staffs with doctrine TTP that are needed to successfully
overcome obstacles. Breaching operations make maneuver possible in the face
of enemy obstacle efforts. Since obstacles may be encountered anywhere,
maneuver forces integrate breaching operations into all movement plans.

When possible, enemy minefields are bypassed to maintain the momentum
and conserve critical countermobility assets. However, when making the
decision to bypass rather than breach, consider the likelihood of friendly units
being channelized into kill zones. Bypassing is done by maneuvering around a
minefield or, if aviation assets are available, moving over the minefield. When
maneuvering around an obstacle, attempt to locate a portion of the force in
overwatch positions to cover the bypass of the main element. Even when the
decision is madetoconduct a breach, scouts should continue to reconnoiter for
bypass routes.

The first step in understanding breaching operations is to know the obstacle
breaching theory. Knowing the theory behind breaching operations equips the
engineer and the maneuver commander with fundamentals that are needed to
integrate breach into the tactical planning, preparation, and execution of an
operation.

Successful breaching operations are characterized by the application of the
following tenets of breaching:

Intelligence

I n any operation where enemy obstacles interfere with friendly maneuver,
obstacle intelligence (OBSTINTEL) becomes a priority intelligence
requirement (PI R). Finding enemy obstacles or seeing enemy obstacle activity
validates and refines the S2's picture of the battlefield. OBSTI NTEL helps
determine enemy intentions, plans, and strength. The force engineer is the
unit's expert on enemy countermobility, and he assists the S2 in templating
enemy obstacles and analyzing OBSTINTEL.

When collecting OBSTI NTEL, reconnaissance is a combined arms activity
that includes engineers. An engineer squad moves with scouts or the patrol
and conducts dismounted reconnaissance of tempi ated or discovered obstacles.
Additional information on reconnaissance can be found in FM 5-170.
Reconnaissance teams gather the following OBSTINTEL information from
the reconnaissance:

• Minefield location. Plot the perimeter location on a large-scale map
and refer to recognizable landmarks.

9-2 Countermine Operations

FM 20-32

• Perimeter description. Describe how the perimeter is fenced. If it is
unfenced, describe how it is marked. If it is unmarked, show how it
was recognized.

• Nuisance mines. If you discover a nuisance mine forward of the
minefield's outer edge, remember, there may be others. Assembly
areas might also be mined.

• Types of mines. Indicate whether mines are AT or AP or have
unknown fuses (self-neutralized or SD). If possible, recover specimens
of unknown or new mines and note the details.

• Details of any other devices. Describe booby traps, trip wires, and
flares.

• Laying method. Indicate whether mines are buried or surface-laid.

• Density and pattern. Include the mine spacing and the number of
mine rows; estimate the mine density based on this information.

• Minefield depth. Provide the distance between strips or rows and
describe markers.

• Safe lanes and gaps. Plot the location of suspected safe lanes and gaps
and describe their markings.

• Ground conditions. I nclude information on general ground conditions.

• Other obstacles. Plot the location and the construction of other
obstacles.

• Enemy defenses. Describe the enemy's location and size. I nclude the
location of enemy direct-fire weapons.

NOTE: Engineers engaged in reconnaissance for OBSTINTEL should
rarely, if ever, be used to reduce obstacles during the reconnaissance.

Each reconnaissanceteam commander submits a detailed OBSTINTEL report
to the next higher headquarters when the reconnaissance is complete. A
sample OBSTINTEL report is shown in Figure 9-1.

Letter
Designation

Explanation

A

Map sheet(s).

B

Date and time the information was collected.

C

Type of minefield (AT, AP, or mixed).

D

Grid references of minefield extremities, if known.

E

Depth of minefield.

F

Estimated time required to clear the minefield.

G

Estimated material and equipment required to clear the minefield.

H

Routes for bypassing the minefield, if any.

l-Y

Grid references of lanes (entry and exit) and width of lanes, in meters.

Z

Additional information such as types of mines used, unknown mines, or types of
booby traps.

Figure 9-1. Sample OBSTINTEL report

Countermine Operations 9-3

FM 20-32

Fundamentals

Suppress

Obscure

Secure

Reduce

Suppress, obscure, secure, and reduce (SOSR) are the breaching fundamentals
that must be applied to ensure success when breaching against a defending
enemy. ThisTTP will always apply but may vary based on specific situations.

Suppression is the focus of all available fires on enemy personnel, weapons,
and equipment to prevent effective fires on friendly forces. The purpose of
suppression is to protect forces who are reducing the obstacle and
maneuvering through it and to soften the enemy's initial foothold.

Obscuration hampers enemy observation and target acquisition, and it
conceals friendly activities and movement. Obscuration smoke deployed on or
near the enemy position minimizes the enemy's vision.

The force secures the breaching site to prevent the enemy from interfering
with reduction and to prevent the enemy's passage through lanes created
during reduction. In general, enemy tactical obstacles are secured by fires,
and protective obstacles are secured by force.

Reduction means creating lanes through or over the obstacle to allow passage
of the attacking force. The lanes must be sufficient to allow the force to cross
and accomplish the mission. (Table 9-1 provides information on lane widths.)
The unit reducing the minefield marks the minefield and lane locations and
reports their conditions to higher headquarters.

Table 9-1. Lane widths

Lane

Width

Remarks

Assault footpath

1 meter

Allows passage of dismounted troops so that they may continue
an attack or secure the far side of a minefield while vehicle
lanes are being breached

Initial lane

4.5 meters

Allows passage of breaching and assault forces (initial lanes
are widened and marked as soon as the tactical situation
allows)

Intermediate lane

4.5 meters

Upgrades sign posting and further defines exit markers

Full lane

10 meters

Allows passage of two-way traffic

Organization

Support Force

The commander organizes the force to accomplish SOSR breaching
fundamentals quickly and effectively. This requires him to organize support,
breach, and assault forces with the necessary assets to accomplish their
missions.

The support force is primarily responsible for eliminating the enemy's ability
to interfere with the breaching operation. It must isolate the battlefield with
fires and suppress enemy fires that are covering the breach location. This
involves massive direct and indirect fire to destroy enemy vehicles and
personnel who are able to bring fire on the breach force.

9-4 Countermine Operations

Breach Force

Assault Force

Mass

FM 20-32

The breach force creates lanes that enable the assault force to pass through
the obstacle and continue the attack. It is also responsible for marking lanes
(length and entry points) to speed passage of assault and follow-on forces. The
breach force is a combined arms force. It includes engineers, breaching assets,
and enough maneuver force to provide local security. The breach force must be
able to deploy and begin reducing the obstacle as soon as enemy fires have
been suppressed. It must be capable of creating a minimum of one lane for
each assaulting company or two lanes for an assaulting TF. At a minimum,
the lanes must be marked and their locations and conditions reported to
higher headquarters and follow-on units as prescribed in the unit's SOP. The
commander should expect a 50 percent loss of mobility assets in close combat.

The assault force destroys or dislodges the enemy on the far side of the
obstacle. It secures the far side by physical occupation in most breaching
operations. The assault force may be tasked to assist the support force with
suppression while the breach force reduces the obstacle. The assault force
must be sufficient in size to seize objectives that eliminate fires on the
breaching site.

Breaching is conducted by rapidly applying concentrated force at a designated
point to crack the obstacle and rupture the defense. Massed combat power is
directed against an enemy weakness. Smoke and terrain help isolate the
enemy force that is under attack. The commander also masses engineers and
breaching equipment to reduce the obstacle. The breach force is organized and
equipped to use several different reduction techniques in case the primary
technique fails (a key vehicle is destroyed or casualties render dismounted
engineers ineffective). Additional reduction assets are present to handle the
unexpected (50 percent over the requirement are normally positioned with the
breach force).

Synchronization

Breaching operations require precise synchronization of the SOSR breaching
fundamentals by support, breach, and assault forces. Failure to synchronize
effective suppression and obscuration with reduction and assault can result in
rapid, devastating losses of friendly troops in the obstacle or the enemy's fire
sack. The commander cannot adequately synchronize his force's application of
combat power in the short time available to him when he encounters an
obstacle. The number of decisions that he must make while under fire in an
unclear situation will rapidly overwhelm him. Even with a force trained to
execute a combined arms breach, synchronizing all the necessary tasks
remains a complex, difficult process. The commander uses the following
principles to ensure synchronization through proper planning and force
preparation:

• Detailed reverse planning.

• Clear subunit instructions.

• Effective C 2 .

• A well-rehearsed force.

Countermine Operations 9-5

FM 20-32

CLEARING OPERATIONS

Clearing is the total elimination or neutralization of mines from an area. It is
not usually conducted under enemy fire, but it can be conducted by engineers
during war or after hostilities as part of nation assistance.

A limited clearing operation can be conducted by follow-on engineers after the
breaching force has reduced the minefield and secured the area. Engineers
initially improve existing breach lanes by widening and marking them, and
they also clear and mark new lanes through the minefield. The clearing
operation supports the continued passage of forces.

A clearing operation is also conducted to eliminate all the mines in a minefield
(previously identified, reported, and marked in a friendly AO) that hinders
mobility or is a hazard to friendly forces.

Upgrade of Breach Lanes

Lane clearance is more deliberate than lane breaching and normally takes
longer. Follow-on engineers upgrade breach lanes to improve existing lanes
through minefields and to create new lanes. This clearing operation is
intended to further reduce the minefield so that follow-on units can pass
through it quickly.

The breach force that initially reduced the obstacle and marked the lanes
turns over the lanes to follow-on engineers. Follow-on engineers can expect
lane widths of 4.5 meters. The total number of lanes depends on the size of the
lead assault force. Two to four assault lanes are normal if the lead unit was
brigade-size.

If forces continue to pass through existing lanes while further reduction and
clearance is conducted, follow-on engineers first begin reducing new lanes. At
a minimum, two lanes are required for an assaulting TF and one lane is
required for an assaulting company/team.

A limited amount of mechanical breaching assets is available for clearing
operations. Follow-on engineers will probably not have tank- mounted mine-
clearing blades (MCBs) or mine-clearing rollers (MCRs). The main mechanical
clearing asset is an armored dozer with a mine rake. M ine-clearing line
charges (M ICLICs) are used if available. Engineers conducting clearing
operations—

• Ensurethat lanes area minimum of 100 meters apart.

• Reduce additional lanes by using the equipment and techniques
outlined in Chapter 10.

• Widen lanes to 10 meters to allow two-way traffic.

• Mark breach lanes by using the original marking system or the
division SOP. (Marking procedures areoutlined in Chapter 10.)

• Empl ace entrance, exit, and left and right lane markers to provide day
and night capability.

Traffic control is critical during lane reduction and when shifting lanes to
improve existing lanes. Engineers conducting reduction and clearance may
also provide guides at the lanes. Control procedures are outlined in F M
90-13-1.

To eliminate the danger of forces entering the minefield adjacent to lanes, the
minefield is marked with fencing (barbwireor concertina) and mine markers.

9-6 Countermine Operations

C2, FM 20-32

Marking is emplaced across the front, on both sides, between lanes, and to the
left and right of the crossing site as far out as practical.

Engineers may also help remove damaged vehicles from minefield lanes.
Recovery vehicles should be available near lanes for this purpose.

Area Clearance

Demining

Clearing operations are done when engineers receive a mission to clear an
area of mines or to clear a specific minefield in a friendly AO. The minefield
was reported and may already be marked on all sides. The worst case would
be if the minefield was reported but not marked and its limits were unknown.
The engineer unit receiving the mission bases plans on available information
and prepares equipment based on the estimate. Detailed techniques and
procedures for area and route clearance operations areoutlined in Chapter 11.

Actions at the minefield begin with a thorough reconnaissance to identify the
minefield limits and the types of mines. This is a time-consuming process that
is hazardous to shortcut. Identified limits are marked with an expedient
system of single-strand barbwire or concertina. I n this situation, since all
mines must be destroyed, the unit takes a systematic approach to clearing
mines. The procedure depends on the types of mines and whether the mines
are buried or surface-laid.

If mines are magnetic- or seismic-fused, mechanical assets are used. Pressure
mines can be destroyed by using hand-emplaced explosives. When a manual
procedure is used, el i mi nate trip wires on AP mines with grapnel hooks before
movi ng forward to detect mi nes.

Using the manual procedure, engineers visually detect mines or detect them
with mine detectors and probes. They also mark mines for destruction by
explosives. Chapter 11 contains information on minesweeping procedures.

After the mines aredestroyed, engineers proof used lanes and routes to ensure
that all the mines were eliminated. This is done by using a mine roller or
another blast-resistant device. Proofing is discussed further in Chapter 10.

Demining is the complete removal of all mines and UXO to safeguard the
civilian population within a geopolitical boundary after hostilities cease. It is
an extremely manpower- and time-intensive operation and is sometimes
contracted. Although not a formal Army mission or function, SOFs may
provide special expertise in training demining organizations, acting as
advisors, and taking the lead in providing clearance equipment or techniques
that can be useful in demining operations. Demining TTP areoutlined in TC
31-34.

Countermine Operations 9-7

FM 20-32

9-8 Countermine Operations

C2

Chapter 10

Minefield Reduction

Reduction is the physical creation of a lane through a minefield. It is a
fundamental of breaching operations as discussed in Chapter 9 and in FM
3-34.2. A number of tasks (detecting, reporting, reducing, proofing, and
marking) directly support or are included in minefield reduction.

DETECTING

Visual

Detection is the actual confirmation and location of mines. It may be
accomplished through reconnaissance, or it may be unintentional (such as a
vehicle running into a mine). Mine detection is used in conjunction with
intelligence-gathering operations, minefield bypass reconnaissance, and
breaching and clearing operations. There are four types of detection
methods— visual, physical (probing), electronic, and mechanical.

Visual detection is part of all combat operations. Personnel visually inspect
the terrain for the following minefield indicators:

Tripwires.

Signs of road repair (such as new fill or paving, road patches, ditching,
culvert work).

Signs placed on trees, posts, or stakes. Threat forces mark their
minefields to protect their own forces.

Dead animals.

Damaged vehicles.

Disturbances in previous tire tracks or tracks that stop unexplainably.

Wires leading away from the side of the road. They may be firing wires
that are partially buried.

Odd features in the ground or patterns that are not present in nature.
Plant growth may wilt or change color, rain may wash away some of
the cover, the cover may sink or crack around the edges, or the
material covering the mines may look like mounds of dirt.

Civilians. They may know where mines or booby traps are located in
the residential area. Civilians staying away from certain places or out
of certain buildings are good indications of the presence of mines or
booby traps. Question civilians to determine the exact locations.

Pieces of wood or other debris on a road. They may be indicative of
pressure or pressure-release F Ds. These devices may be on the surface
or partially buried.

Minefield Reduction 10-1

FM 20-32

Physical

Patterns of objects that could be used as a sighting line. The enemy
can use mines that are fired by command, so road shoulders and areas
close to the objects should be searched.

Physical detection (probing) is very time-consuming and is used primarily for
clearing operations, self-extraction, and covert breaching operations.
Detection of mines by visual or electronic methods should be confirmed by
probing. Use the following procedures and techniques when probing for mines:

• Roll up your sleeves and remove your jewelry to increase sensitivity.
Wear a Kevlar helmet, with the chin strap buckled, and a protective
fragmentation vest.

• Stay close to the ground and move in a prone position to reduce the
effects of an accidental blast. When moving into a prone position—

— Squat down without touching your knees to the ground.

— Scan forward up to 2 meters and to the sides up to 3 meters for
mine indicators.

— Probe the area around your feet and as far forward as possible.

— Kneel on the ground after the area is found to be clear, and
continue probing forward until you are in a prone position.

• Use sight and touch to detect tripwires, fuses, and pressure prongs.

• Use a slender, nonmetallic object as a probe.

• P robe every 5 centi meters across a 1-meter front.

• Gently push the probe intotheground at an anglethat is less than 45
degrees.

DANGER
Use extreme caution when probing. If the probe is pushed
straight down, its tip may detonate a pressure fuse.

Apply just enough pressure on the probe to sink it slowly into the
ground.

If the probe encounters resistance and does not go into the ground
freely, carefully pick the soil away with the tip of the probe and remove
the loose dirt by hand. Care must betaken to prevent functioning the
mine.

When you touch a solid object, stop probing and use two fingers from
each hand to carefully remove the surrounding soil and identify the
object.

If the object is a mine, remove enough soil to show the mine type and
mark its location. Do not attempt to remove or disarm the mine. Use
explosives to destroy detected mines in place, or use a grappling hook
and rope to cause mines to self-detonate. Do not use metal grappling
hooks on magnetic-fused mines.

10-2 Minefield Reduction

C2, FM 20-32

Electronic

Probing is extremely stressful and tedious. The senior leader must set a limit
to the time a prober can actually probe in the minefield. To determine a
reasonable time, the leader must consider METT-TC factors, weather
conditions, the threat level, the unit's stress level, and the prober's fatigue
level and stateof mind. Asa rule, 20 to 30 minutes is the maximum amount of
time that an individual can probe effectively.

Electronic detection is effective for locating mines, but this method is time-
consuming and exposes personnel to enemy fire. I n addition, the suspected
mines must be confirmed by probing.

AN/PSS-12 Mine Detector

TheAN/PSS-12 mine detector (Figure 10-1) can only detect metal, but most
mines have metal components in their design. The detector can locate and
identify plastic or wooden mines by a slight metallic signature. Employment
and operation procedures for the AN/PSS-12 are discussed in Appendix F, and
technical data is available in TM 5-6665-298-10. The detector is hand-held
and identifies suspected mines by an audio signal in the headphones.

Figure 10-1. AN/PSS-12 mine detector

As in probing, consideration must betaken for the maximum amount time an
individual can operate the detector. The leader considers METT-TC factors,
weather conditions, the threat level, the unit's stress level, and the
individual's fatigue level and stateof mind. As a rule, 20 to 30 minutes is the
maximum amount of time an individual can use the detector effectively.

Airborne Standoff Minefield Detection System

TheAirborne Standoff Minefield Detection System (ASTAMIDS) (Figure 10-2,
page 10-4) provides US forces with the capability to detect minefields rapidly.
Environmental conditions must be favorable for aircraft and ASTAMIDS
operations. ASTAMIDS can be mounted on a UH-60 Blackhawk helicopter, an
unmanned aerial vehicle (UAV), or a fixed-wing aircraft. The system detects

Minefield Reduction 10-3

FM 20-32

and classifies thermal and other anomalies as suspected minefields along
routes or in areas of interest. ASTAM I DS can be used to protect advancing
forces and can operate in concert with air and ground units in reconnaissance
missions.

Figure 10-2. ASTAMIDS

System Components

ASTAM I DS hardware and software components consist of a sensor with
associated electronics and the minefield-detection algorithm and processor
(M I DAP). Surrogate equipment includes an air-data package (GPS, radar
altimeter, inertial measurement unit [I ML)]), a power supply, a work
station(s), a digital data recorder, mounting racks, and a modified floor for the
specific aircraft.

Operators view the data displayed on the monitors, communicate with the
aircrew, and perform other functions (such as changing data tapes and
producing reports). The aircrew must maintain an altitude of 300 feet and an
airspeed of approximately 70 knots for the system to detect mines accurately
within the sensor's ground swath (approximately 215 feet wide). The system
has a 2-hour operational capability, based on standard flight time for the
mission profile.

Employment Concept

ASTAM I DS is a fast method for detecting tactical minefields. When it is
employed by aviation elements in support of maneuver units, close
coordination between aviation and ground units assures that minefield
detection is reported accurately and quickly. ASTAM I DS is not as precise as
ground detection systems, but it is accurate enough to help mitigate the
dangers inherent with minefields. It can be used in both friendly and enemy
territories. The use of a Blackhawk ASTAMIDS in areas of threat observation

10-4 Minefield Reduction

FM 20-32

and fire must be planned and coordinated very carefully, because a helicopter
is extremely vulnerable whileflying the mission profile required for detection
(steady altitude, speed, and path).

Once airborne and at its start point, the ASTAMIDS system is placed in the
correct detection mode, based on the intended mission (route or area
reconnaissance). When the system indicates an initial detection, the operator
communicates it to the pilot. The pilot then flies a verification pass over the
indicated area. If the system again indicates a detection, the pilot resumes the
mission (route reconnaissance) or continues the survey pattern to determine
the minefield borders (area reconnaissance). If no detection is indicated on the
verification pass, the operator instructs the pilot to resume the flight plan.

I nterim Vehicle-Mounted Mine Detector

The interim vehicle-mounted mine detector (IVMMD) is used in all levels of
conflict and OOTW. The IVMMD is mounted on a blast- and fragmentation-
survivable vehicle; it is designed to detect and mark buried and surface-laid,
metallic AT mines. The primary mission of the I VM M D is to detect mines
during route clearance. The system should not be used when operating in an
environment wheretheenemy employs mines that are not pressure-fused.

System Components

A complete I VM M D (Figure 10-3) consists of one mine-detection vehicle
(MDV), one towing/mine-detection vehicle (T/MDV), three mine detonation
trailers, a spare-wheel module for the MDV, a spare-wheel module for theT/
M DV, and a container of spare parts.

Mine detonation
trailers

Figure 10-3. IVMMD components

The MDV's only mission is to detect mines. It can negotiate vertical slopes up
to a 20 percent grade. The MDV employs a 4-cylinder engine and a manual
transmission to propel the4.8-ton vehicle with a 3-meter-wide detection array.
The detection array consists of two separate induction coils (one for the left
side and one for the right side) that detect magnetic fields below the vehicle.

Minefield Reduction 10-5

FM 20-32

The detection array is suspended between the two axles of the vehicle. When
thedetector encounters a metallic object, the operator is notified by an audible
signal in the earphone. A visual signal appears on the dashboard that denotes
which side of the array detected the object. The operator then stops the
vehicle, backs it up, and reencounters the metallic object. (The M DV has two
detection modes— the locate mode is used to identify the metal object, and the
pinpoint mode is used to find the center of the object.) When the operator
encounters the strongest signal, he activates the marking system (a nozzle
mounted on the rear frame and centered on each detection array) that deploys
a water-based ink onto the roadway.

The T/M DV has a 6-cylinder engine and the same detection and marking
system as the M DV. The T/M DV tows three detonation trailers. The
recommended maximum operating speed while towing the trailers is 20 kph.
The T/M DV (with trailers) can negotiate vertical slopes up to a 20 percent
grade; however, going down such slopes is difficult. The T/M DV must be in
first gear, and the trailer brakes must be deployed to decrease the speed of the
vehicle when going down a slope.

The mine detonation trailers are very heavy, and they are specifically
designed to apply heavy ground pressure that initiates pressure-activated
mines. Each trailer has two axles of different lengths so that the three trailers
provide a full 3-meter-wide proofing capability behind the T/M DV. If a mine
detonates underneath the trailers, the wheel bolts are designed to sheer so
that repair is limited to replacing a single wheel.

The detection array is suspended between the two axles of the MDV Although
the vehicle is designed to produce very little ground pressure, it will detonate
most pressure-fused mines, depending on the sensitivity of their fuses.

• The MDV produces 27.9 pounds per square inch (psi) of ground
pressure when the tires are inflated to 14.5 psi and 21.8 psi of ground
pressurewhen the tires are inflated to 8.7 psi.

• The T/M DV produces 49.8 psi of ground pressure when the tires are
inflated to 29 psi and 23.4 psi of ground pressurewhen the tires are
inflated to 8.7 psi.

Employment Concept

Mechanical

The I VM M D is used to support route-clearance operations. Clearance
operations ensure that LOC are safe for the passage of personnel and
equipment. The IVMMD should not be used during hours of limited visiblity,
because it hampers the operator's ability to see surface-laid mines and visual
signatures that indicate mining activities.

The track-width mine roller is a mechanical minefield-detection system. It is
most effectively deployed to lead columns on route movement, but it can be
used to precede tactical formations. I n column movement, unit vehicles travel
a narrow path, and one or two mine rollers can effectively detect mines in the
path. Mine rollers can also be used to detect minefields in front of deployed
tactical formations; however, more than one roller is required for a good
probability of detection.

10-6 Minefield Reduction

REPORTING

REDUCING

FM 20-32

I intelligence concerning enemy minefields is reported by the fastest means
available. Spot reports (SPOTREPs) are the tactical commander's most
common source of minefield intelligence. They originate from patrols that
have been sent on specific minefield reconnaissance missions or from units
that have discovered minefield information in the course of their normal
operations. The information is transmitted to higher headquarters.

Minefield reduction and clearing equipment is broken down into explosive,
mechanical, electronic, and manual. Combat engineers and the operators of
breach assets practice and become proficient in these reduction means. They
integrate them into the breach drills of the units they support. The team
applies different TTP to breach drills and prepares and rehearses them as
part of theTF plan.

Explosive

M58A4 Mine-Clearing Line Charge

TheMICLIC (Figure 10-4, page 10-8) is a rocket-propelled, explosive line
charge. It is used to reduce minefields that contain single-impulse, pressure-
activated AT mines and mechanically activated AP mines. It clears a 14- by
100-meter path. The M ICLIC has a 62-meter standoff distance from the
launcher to the detonation point. The M ICLIC's effectiveness is limited
against prong AP mines, magnetically activated mines (including some
SCATMINEs), top-attack mines, side-attack mines, and mines containing
multiple-impulse or delay-time fuses. It also has little effect on other
obstacles, such as log and concrete barriers, antivehicular ditches, and walls.
The shock effect and the psychological impact of the detonation make the
M ICLIC a useful weapon in a close fight or in MOB A.

The M ICLIC is mounted on a rubber-tired trailer, or two M ICLICs can be
mounted on an armored vehicle-launched bridge (AVLB), with the bridge
downloaded, using a fabricated I-beam frame (procedures for mounting the
MICLIContheAVLB are outlined in TM 9-1375-215-14&P). This is called an
armored vehicle-launched M ICLIC (AVLM) (Figure 10-5, page 10-8), and it is
the preferred system because no trailer is involved to hinder the mobility of
the vehicle.

Towing vehicles for the trailer-mounted M ICLIC are a combat engineer
vehicle (CEV), an M113 APC, M2 and M3 Bradleys, an M9 armored combat
earthmover (ACE), a 5-ton wheeled vehicle, and a 2V2-ton wheeled vehicle. The
trailer limits the MICLIC's mobility in rough terrain and degrades the
maneuverability of the towing vehicle, thereby increasing vulnerability. Since
the M ICLIC is critical to the breach, it is kept under the protection of the force
and is moved to the breach site along easily trafficable, covered, and concealed
routes. This effectively prevents the towing vehicle from performing any other
task (firing or maneuvering) or serving as an engineer squad vehicle unless
M ICLIC employment is the squad's only mission. This is an important
consideration when selecting the towing vehicle because this vehicle must be
solely dedicated to the mission.

Minefield Reduction 10-7

FM 20-32

Figure 10-4. MICLIC

Figure 10-5. AVLM

The MICLIC can be fired from within an armored vehicle without exposing
soldiers to fires; however, the prefiring preparations must be done in advance
at a covered and concealed location near the breach site. The initiating cable is
brought into the vehicle through the hatch, which must be left ajar, or through
the portal of the periscope, which has been removed. Therefore, the crew is not
afforded nuclear, biological, chemical (NBC) protection. When the MICLIC is

10-8 Minefield Reduction

FM 20-32

fired from a wheeled vehicle, however, the crew must move to a covered
position outside the backblast area. The special-purpose cable on the firing
control switch is long enough to allow adequate standoff.

The vehicle operator must be proficient in all aspects of preparing and
deploying the MICLIC, including the critical aspect of selecting the optimum
breach site. Although the operator will be directed to the breach site by the
engineer platoon leader or the breach force commander, ensuring that he can
independently accomplish the task will simplify the operation and greatly
enhance its likelihood of success. The towing vehicle and the operator must be
selected well in advance and be dedicated solely to the task. The operator
must be included in all rehearsals and planning sessions and, if possible,
during leaders' reconnaissances.

Each MICLIC trailer transports and fires one charge, and then it must be
reloaded. The AVLM can fire both MICLICs before reloading. The loaded
charge container weighs 1,283 kilograms, so a lifting device such as a 5-ton
wrecker or a HEMTT is needed. Reloading, which can be done by an
experienced crew in about 20 minutes, entails loading a rocket on the rail and
lifting a new charge container onto the launcher. The reloading operation
must be done in a covered and concealed location.

The exact limits and depth of an enemy minefield are seldom known before
the breach. This is particularly true when the situation is unclear, and the
minefield is encountered simultaneously with enemy contact. The first and
only indication that a unit is in a minefield may be when a vehicle encounters
a mine. The leading edge of the minefield still may bean uncertainty, because
the vehicle could have hit a mine in an interior row. The number of M ICLICs
needed to clear a single lane through a minefield depends on the minefield
depth:

• Clearing a lane through a minefield less than 100 meters deep
requires one MICLIC (Figure 10-6, page 10-10). The leading edge of
the minefield is identified and, if possible, confirmed by
reconnaissance. The MICLIC is deployed from a minimum standoff
distance of 62 meters from the leading edge of the minefield.

• Clearing a lane through a minefield more than 100 meters deep or of
uncertain depth requires two or more MICLICs (Figure 10-7, page 10-
10). If the leading edge cannot be identified, the MICLIC is deployed
100 meters from the possible edge or stricken vehicle. When the first
MICLIC is detonated, a second MICLIC moves 25 meters into the first
MICLICs path and fires its charge. This extends the lane an
additional 87 meters. Additional MICLICs are used for minefields of
extreme depth, and each one moves down the lane 25 meters into the
path created by the previous charge.

Minefield Reduction 10-9

FM 20-32

\+ 62 m >■

Inert

Inert

Actual charge

Known to
be <100 m

O O O

§M//Sl

o o o
o o o
o o o

J 00 m

Figure 10-6. MICLIC employment in a minefield less than 100 meters deep

First MICLIC

62 m

100 m

25 m

o o o o
o o o o

I W \-> W KJ W I

i o io o o o ! I

62 m -»4* —100 m — H

, O O O O O r

Second MICLIC

sow

«

h

O O O O O ;

First charges

jj Second charges

- Inert

Figure 10-7. MICLIC employment in a minefield of uncertain depth or greater than 100 meters

10-10 Minefield Reduction

C2, FM 20-32

The neutralization of mines by blast depends on the peak pressure and the
impulse. For the MICLIC, the impulse is at a maximum of 3 meters from the
line charge (on both sides) and decreases the closer it gets toward the line
charge, to a minimum of 1 meter from the line charge. This decrease on
impulse causes a skip zone (Figure 10-8). This does not mean that
neutralization is equal to zero percent; it means that it is not equal to 100
percent. M ines that are buried deeper than 10 centimeters and located 1 to 2
meters from the line charge have a high probability of not being neutralized.

Skip zone

' . ' . ' vu^ ' u:-: 1 :.

Skip zone

Figure 10-8. Skip zone

5 m
4 m
3 m
2 m
1 m
a Line charge

1 m

2 m

3 m

4 m

5 m

Minefield Reduction 10-11

C2, FM 20-32

Antipersonnel Obstacle Breaching System

The Antipersonnel Obstacle Breaching System (APOBS) (Figure 10-10) is a
man-portable device that is capable of quickly creating a footpath through AP
mines and wire entanglements. The APOBS is normally employed by combat
engineers, infantry soldiers, or dismounted armored cavalry personnel. The
APOBS provides a lightweight, self-contained, two-man, portable line charge
that is rocket-propelled over AP obstacles from a standoff position away from
the edge of the obstacle.

For dismounted operations, the APOBS is carried in 25-kilogram backpacks
by no more than two soldiers for a maximum of 2 kilometers. One backpack
assembly consists of the rocket-motor launch mechanism, containing a 25-

10-12 Minefield Reduction

FM 20-32

Figure 10-9. APOBS

meter line-charge segment and 60 attached grenades. The other backpack
assembly contains a 20-meter line-charge segment and 48 attached grenades.
The total weight of theAPOBS is approximately 54 kilograms. It is capableof
breaching a footpath that is approximately 0.6 by 45 meters and is fired from
a 25-meter standoff.

M1A1/M1A2 Bangalore Torpedo

The bangalore torpedo (Figure 10-11) is a manually emplaced, explosive-filled
pipe that was designed as a wire breaching device, but it is also effective
against simple pressure-activated AP mines. It is issued as a demolition kit
and consists often 1.5-meter tubes. Each tube contains 4 kilograms of high
explosives and weighs 6 kilograms. The kit clears a 1- by 15-meter lane.

Figure 10-10. Bangalore torpedo

The bangalore torpedo is used by dismounted infantry and engineer troops.
An individual soldier or a pair of soldiers connects the number of sections
needed and pushes the torpedo through the AP minefield before priming it. A

Minefield Reduction 10-13

FM 20-32

detailed reconnaissance is conducted before employing the bangalore torpedo
to ensure that trip wires have not been used.

The bangalore torpedo generates one short impulse and is not effective
against pronged, double-impulse, or pressure-resistant AP and AT mines.

WARNING
Do not modify the bangalore torpedo. Cutting the
bangalore in half or performing any other modification
could cause the device to explode.

Mechanical

MCBs and MCRs are fielded as armor battalion sets that contain 12 MCBs
and 4 MCRs. Blades clear lanes through minefields, while rollers are used to
detect minefields and proof lanes created by other means. Rollers are not a
good primary system for lane reduction because multiple mine detonations
destroy the roller system and the vehicle pushing it. (The roller is designed to
resist two conventional-mine or three scatterable-mine strikes, depending on
the mine type.)

The CE V, the ACE, and dozer blades were not designed for breaching
minefields and should be employed only as a last resort, because using them is
extremely hazardous to the crew and equipment. However, CEVs or ACEs can
effectively clear a lane through AP scatterable minefields because they
sustain little or no damage and offer protection to the crew. When using a
dozer to clear a path through minefields, the operator is exposed to mine
effects. Before clearing begins, the operator's cabin should be sandbagged or
up-armored and the lane should be cleared of trip wires. When using an
engineer blade to clear a path through a scatterable minefield, use the skim
technique (Figure 10-12). Start skimming 100 meters from the suspected
minefield leading edge.

Mine-Clearing Blade

The MCB (Figure 10-13) is used to remove land mines from the minefield. It
consists of a blade arrangement with scarifying teeth to extract mines, a
moldboard to cast mines aside, and leveling skids to control the depth of the
blade.

The MCB lifts and pushes mines, which are surface-laid or buried up to 31
centimeters deep, to the side of the track-width lanes. The blade has three
depth settings— 21, 25, and 31 centimeters. The blade creates a 1.5-meter
cleared path in front of each track. Figure 10-14, page 10-16, shows inside
clearance distances between tracks of common track vehicles in relationship
to the uncleared area left by the MCB.

Mines armed with AHDs, magnetic fuses, or seismic fuses may be activated
when they are lifted by the blade; and they may disablethe blade. Mines lifted
by the blade are left in the spoil on each side of the furrowed path and remain
a hazard until they are removed. Double-impulse mines that are lifted into the
spoil on the side have a probability of functioning into the hull of the plowing
vehicle. The skid shoe for each blade exerts adequate pressure to activate

10-14 Minefield Reduction

FM 20-32

• •

• •

• •

• •

Figure 10-11. Skim technique

J33S?

Lffii

I

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Figure 10-12. MCB

most single-impulse mines, which effectively clears a section of thecenterline
by explosive detonation. This action may disable the blade. Multiple-impulse
pressure fuses encountered by the skid shoe are not defeated. A dog-bone
assembly between the blades defeats tilt-rod mines. The improved dog-bone
assembly (I DA) projects a magnetic signature and defeats tilt-rod and
magnetic mines.

The MCB weighs approximately 3,150 kilograms and can be mounted on an
Ml tank without special preparation or modification. Mounting requires lift
capability and takes up to an hour, so it must be mounted well in advance of
the mission. It is not easy to mount or transfer the MCB to another tank
under battlefield conditions.

Minefield Reduction 10-15

FM 20-32

457 cm
163 cm
137 cm

B-«- 66 cm -J

Plowed path

226 cm
. 221 cm
201 cm
191 cm
183 cm

Uncleared
strip

M60A3

,M88

M2/M3

M113

Figure 10-13. Mine-blade width compared to track-vehicle widths

Once mounted, an electric motor raises and lowers the blade. When it is in the
raised position, it minimally effects the Mi's maneuverability and speed. This
will not greatly impact the employment of the weapon system except when the
blade is in operation. The MCB is also equipped with an emergency, quick-
disconnect feature.

The M 1 should perform plowing operations from 8 to 10 kph, depending on
soil conditions. It cannot maneuver but must continue in a straight path
through the minefield to avoid damaging the blade. The main gun must be
traversed to the side during plowing because mine detonation under the blade
may cause thegun to be thrown violently intothe air, damaging the tube. The
area selected for the lane must be relatively flat and free of rocks or other
obstacles.

The operator begins plowing approximately 100 meters from the estimated
minefield leading edge. He creates a lane extending another 100 meters
beyond the estimated minefield far edge to ensure that the lane extends
through the entire minefield. M ultiple vehicles crossing the breach will
deepen the cut made by the MCB, and pressure-fused mines left in the
uncleared strip will be dangerous. The uncleared strip should be cleared as
soon as possible.

Mine-Clearing Roller

The MCR (Figure 10-15) consists of a roller assembly, a mounting kit, and a
hand winch kit. The roller assembly weighs approximately 9,072 kilograms
and consists of two push beams mounted to the front of the tank. The rollers

10-16 Minefield Reduction

FM 20-32

are designed to defeat most single-pulse, pressure-activated AT and AP mines.
The roller creates a 1.1-meter-wide cleared path in front of each track.

Figure 10-14. MCR

Figure 10-16 shows inside clearance distances between tracks of common
track vehicles in relationship to the uncleared area left by the MCR. A dog-
bone-and-chain assembly between the rollers defeats tilt-rod mines. The I DA
can befitted to the roller. The roller is designed to withstand multiple mine
explosions before damage; however, this depends on the size of the mines.
Large blasts may destroy the roller or the vehicle or injure the crew.

112cm

407 cm
183 cm

112cm

226 cm

. M1

IP

I

I R3 5 I

221 cm

1 cm
I K/I60A3

,M88
, M2/M3
M113

i

201 cm

i

191 cm

1 83 cm

F

toller

path

Uncleared
strip

Figure 10-15. Mine-roller width compared to track-vehicle widths

Minefield Reduction 10-17

FM 20-32

Panther

The roller can be mounted on an M 1 or M60 tank that is modified with a
permanently attached mine-roller mounting kit. Mounting the roller to a tank
is a cumbersome, time-consuming operation because it is very difficult under
battlefield conditions and requires lift capability. The roller tank is limited to
a speed of 5 to 15 kph. When employed in a suspected minefield, the MCR
must travel in a relatively straight path, because tight turns may cause the
roller to deviate from the path of the track and leave the tank vulnerable to
mines. Ground fluctuations, bumps, and berms may cause the roller to lift
from the ground and miss mi nes.

The MCR is not designed to negotiategaps on its own; however, it can be used
on AVLB caution crossings. I n this situation, the curbing from the bridge is
removed. To prevent damage to the bridge's hydraulic line, the tank driver
uses a strap to lift the dog bone and chain when crossing the bridge. The main
gun must be traversed to the side when a mine encounter is possible or
imminent, because a mine blast can throw the roller or parts of the roller
violently into the air and damage the tube. The main gun should only be fired
from a temporary halt.

When the situation and the mission permit, MCRs may be employed as lead
vehicles to detect minefields. This is most viable when the supported element
is traveling in a column. The roller may also be used to lead a supported
element traveling in a tactical formation other than a column, but it is less
effective than other methods because—

• Vehicles not directly behind the roller may encounter mines passed by
the roller.

• The roller may travel well into or completely through a widely spaced
minefield without encountering a mine, thus giving the formation a
false sense of security.

• A mine encountered by the roller may not be on the leading edge of the
minefield.

• The roller vehicle is extremely vulnerable because it can only use its
weapon system from a temporary halt.

Rollers are best used to proof lanes in obstacles that are breached by other
means, such as a M ICLIC or an MCB. A roller pulling a trailer-mounted
MICLIC can proof a lane created by a M ICLIC that was launched by another
vehicle. The roller then fires the second MICLIC and proofs its own lane.

If rollers participate in a deliberate breach operation or if the force
incorporates rollers into a hasty breach plan, rollers must be mounted before
rehearsals. Unmounted rollers that not being used for the mission are carried
in theTF formation on M916 tractor trailers. Rollers require lift capability
(such as an M88), a secure location, and 30 to 60 minutes to mount on a tank
that is fitted with a mounting kit.

The M60 Panther (Figure 10-17) is one of several developmental countermine
systems used by U S forces during operations,/ oint Endeavor and J oint Task
ForceEagle. The Panther is a remotely controlled vehicle with mine rollers,
and it is used to proof lanes and assembly areas. The system consists of a

10-18 Minefield Reduction

MiniFlail

FM 20-32

turretless M60 tank, Israeli mine rollers, an anti magnetic actuating device,
and an RCU that is mounted in a separate vehicle. Additionally, a remote
video camera allows the operator to see the road ahead.

Figure 10-16. Panther

During route clearance or proofing operations, the Panther is the lead vehicle
on the route. It is followed closely by an armored control vehicle, usually an
M113. The control vehicle contains the Panther operator, the RCU, and the
monitor. The monitor displays the route being proofed or cleared through a
camera mounted on the Panther. The Panther is controlled from the
commander copula or troop hatch of the control vehicle. The control vehicle
should be approximately 200 to 300 meters behind the Panther, and its
hatches should be secured open. Crew members in the control vehicle should
be wearing I mproved Body Armor System, Individual Countermine (I BASIC)
protective garments.

Mine rollers can be raised for limited travel while mounted on the Panther. If
the distance is excessive, the rollers must be transported on a cargo carrier.
Rollers must be adjusted before every mission to ensure that they have
contact with the ground and that their weight is uniformly distributed. To
ensure proper coverage and overlap of rollers, at least three passes should be
conducted. Passes should have a minimum of 30 centimeters overlap. Inside
roller distances are the same as the MCR.

The MiniFlail (Figure 10-18. page 10-20) is a remotely operated, line-of-sight,
AP-mine and UXO neutralization system that was developed for use by US
light forces. It can clear at a rate of 1,200 square meters per hour. The
MiniFlail detonates or disables A P mines from a safe operating distance. The
MiniFlail neutralizes by striking objects with a rotating chain assembly, called
a flail, and clears a foot path approximately 1.1 meters wide. The system
neutralizes AP mines and UXO by detonation, mechanical destruction, or
displacement from the cleared lane. The MiniFlail is approximately 1.3
meters wide, 1.3 meters high, 3 meters long, and weighs 1,100 kilograms. The
system is operated by a hand-held controller that has a maximum range of
300 meters. It is fully armored with a material similar to Kevlar, and thetires

Minefield Reduction 10-19

FM 20-32

are filled with foam. The flail is a self-articulating, hydraulically powered
shaft with 84 chains; each chain is 0.5 meter long.

Ml Grizzly

Figure 10-17. MiniFlail

The Grizzly (Figure 10-19) provides a hasty capability for breaching complex
obstacles of mines, wire, posts, rubble, and tank ditches to create a lane for
other vehicles to follow. The Grizzly's primary features are a full-width, 4.2-
meter MCB and a power arm. The power arm has a reach of 9 meters and a
bucket capacity of 1.2 cubic meters. Its primary missions are to reduce berms
and fill AT ditches.

Figure 10-18. Grizzly

The system is armed with an M240 7.62-millimeter machine gun and an
MK19 40-millimeter grenade launcher. The Grizzly has an Ml-series tank
chassis.

10-20 Minefield Reduction

FM 20-32

The Grizzly lifts and pushes mines, which are surface-laid or buried up to 31
centimeters deep, to the side of full-width lanes. The blade has multiple depth
settings, depending on the mission, and it creates a 4.2-meter-wide cleared
path. When plowing, the Grizzly is restricted to less than 10 kph, depending
on soil conditions. The operator begins plowing approximately 100 meters
from the estimated minefield leading edge. He creates a lane extending
another 100 meters beyond the estimated minefield far edge to ensure that
the lane extends through the entire minefield.

The Grizzly has integrated digital features to enhance battlefield awareness.
Some of the digital features are thermal and video cameras, ground-speed
sensors, terrain-mapping sensors, and an integrated commander's control
station.

Combat Engineer Vehicle with Full-Width Mine Rake

NOTE: The CEV with full-width mine rake will be used in Korea only.

This system consists of a wedge-shaped rake that is mounted to a CEV blade
(Figure 10-20).

Figure 10-19. CEV with mine rake

The rake weighs 2,025 kilograms and is lifted off its transport vehicle with a
HEMTT, a wrecker, an M88, or a CEV boom. The CEV crew uses basic-issue
items to install the rake, and installation takes approximately 30 minutes.
The rake has a skid shoe to maintain a raking depth of 31 centimeters. The
CEV with mine rake provides a vehicle-width clearance (4.5 meters) at 5 to 10
kph. The rake has a quick-disconnect feature. It lifts surface-laid and buried
mines (up to 31 centimeters deep) and pushes them off to both sides.

The CEV with mine rake is used to clear lanes during minefield breaching.
While it can be employed as the first breaching asset into a minefield, a
MICLIC should be used first to eliminate as many mines as possible. The rake
is then used to proof the lane. The system can pull a MICLIC and fire it before
proofing. Raking begins 100 meters before the minefield and continues 100
meters beyond the suspected limit. The CEV maintains a straight course
through the minefield. If the skid shoe is damaged, the operator reduces speed
and manually controls the blade depth. This is very difficult and risky.

Minefield Reduction 10-21

FM 20-32

Mine-Clearing/Armor -Protection Kit

Electronic

The mine-clearing/armor-protection kit (MCAP) consists of two parts— the
mine-clearing rake and the armor protection.

The rake uses a tine that is mounted on a diagonal beam. The rake assembly
is designed to sift through the soil, lift out mines, and windrow buried and
surface-laid mines to the right of the vehicle. The system clears a 30-
centi meter-deep path through a minefield. The rake has a skid shoe that acts
as a depth control guide for the operator.

The armor protects the crew against mine blast, small-arms fire, and artillery
fire. Protection is also provided for the engine, the fuel tank, and exposed
hydraulic cylinders and lines. Ballistic glass blocks are provided at each vision
port to permit unrestricted view and operation of the vehicle and the
equipment.

The MCAP is mounted on a D7 dozer to perform minefield breaching and lane
widening. Proofing the lane must be conducted after the dozer has cleared the
lane. SomeAP mines may still be I eft in the lane.

The Field- Expedient Countermine System (FECS) is a series of copper coils
that fit over the front of tracked and wheeled vehicles. Power is supplied by
the vehicle's battery. The coil emits a large magnetic signature that detonates
magnetically fused mines located 2 to 5 meters in front of the vehicle. The
FECS is designed to defeat magnetically influenced mines only and must be
used with other countermine systems.

Manual

When stealth is required or advanced mechanical equipment is unavailable,
manual breaching procedures can be used. Engineers use hand-emplaced
explosives, grapnel hooks attached to ropes, probes, mine detectors, and hand-
emplaced marking equipment to manually breach obstacles. This is the only
method that works in all situations and under all conditions because certain
types of terrain, weather, and sophisticated fuses can severely degrade the
effectiveness of rollers, plows, and line charges.

Surface-Laid Minefields

The enemy possesses a significant mechanical, mine-burying capability. It has
the capacity and the propensity for the labor-intensive effort required to bury
mines by hand; however, the enemy often lays mines on the surface. Buried
mines are usually found in a highly prepared defense that requires a
deliberate breach operation. Training and execution of surface and buried
minefield breaches should always assume the presence of AHDs and trip
wires until proven otherwise.

From covered positions, the engineers first use grapnel hooks to check for trip
wires in the lane. The limited range of the tossed hook requires the procedure
to be repeated through the estimated width of the obstacle. A demolition team
then moves through the lane. The team places a line main down the center of
the lane, ties the line from theexplosives into the line main, and places blocks
of explosives next to surface-laid mines. After the mines are detonated, the

10-22 Minefield Reduction

FM 20-32

team makes a visual check to ensure that all of the mines were cleared before
directing a proofing roller and other traffic through the lane.

Manual procedures must be well-practiced. Members of the demolition team
are assigned special tasks, such as grappler, detonating-cord man, and
demolitions man. All of the members should be cross-trained on all the
procedures. Demolitions are prepared for use before arriving at the breach
site. An engineer platoon uses squads in series through the minefield to clear
a lane for a company team. The platoon must rehearse reduction procedures
until execution is flawless, quick, and technically safe. During the breach, the
engineer platoon will be exposed in the lane for 5 minutes or more depending
on the mission, the minefield depth, and the platoon's level of training.

Buried Minefields

Manually reducing a buried minefield is extremely difficult to perform as part
of a breaching operation. It is usually part of a clearance operation. If the
mine burrows are not easily seen, mine detectors and probes must be used to
locate the mines. The mines are then destroyed by hand-emplaced charges. As
an alternative, the mines can be removed by using a grappling hook and, if
necessary, a tripod (Figure 10-21). Using a tripod provides a vertical lift on the
mine, making it easier to pull the mine out of the hole.

Figure 10-20. Tripod

The platoon leader organizes soldiers into teams with distinct, rehearsed
missions including grappling, detecting, marking, probing, and emplacing
demolitions and detonating cord. The platoon is exposed in the obstacle for
long periods of time.

Grappling Hook

The grappling hook (grapnel) is a multipurpose tool that is used for manual
obstacle reduction. Soldiers use it to detonate mines from a standoff position
by activating trip wires and AHDs. After the grapnel is used to clear the trip
wires in a lane, dismounted engineers can move through the minefield,
visually locate surface-laid mines, and prepare the mines for demolition. I n
buried minefields, soldiers grapple, then enter the minefield with mine
detectors and probes.

There two types of grapnel hooks— hand-thrown and weapon-launched.

Minefield Reduction 10-23

FM 20-32

Hand-Thrown

A 60-f-meter light rope is attached to the grapnel for hand-throwing. The
throwing range is usually no more than 25 meters. The excess rope is used for
the standoff distance when the thrower begins grappling. The thrower tosses
the grapnel and seeks cover before the grapnel and rope touch the ground in
case their i impact detonates a mine. He then moves backward, reaches the end
of the excess rope, takes cover, and begins grappling. Once the grapnel is
recovered, the thrower moves forward to the original position, tosses the
grapnel, and repeats the procedure at least twice. He then moves to the end of
the grappled area and repeats this sequence through the depth of the
minefield.

Weapon-Launched

PROOFING

MARKING

A 150-meter light rope is attached to a lightweight grapnel that is designed to
be fired from an M16A1 or M16A2 rifle using an M855 cartridge. The grapnel
is pushed onto the rifle muzzle, with the opening of the retrieval -rope bag
oriented toward the minefield. Thefirer is located 25 meters from the leading
edge of the minefield, and he aims the rifle muzzle at a 30- to 40-degree angle
for maximum range. Once fired, the grapnel will travel 75 to 100 meters from
thefirer's position. After the weapon-launched grapnel hook (WLGH) has
been fired, the firer secures the rope, moves 60 meters from the minefield,
moves into a prone position, and begins to grapnel. The WLGH can be used
only once, but it can be reused up to 20 times for training (blanks are used to
fire the grapnel for training).

Multiple grapplers can clear a lane of trip wires quickly and thoroughly, but
they must time their efforts and follow procedures simultaneously, if possible.
A hit on a trip wire or a pressure fuse can destroy the hook and the cord, so
engineers should carry extras.

Proofing is done by passing a mine roller or another mine-resistant vehicle
through the minefield as the lead vehicle to verify that a lane is free of mines.
An MCB, a Panther, a M iniFlail, or an MCR can be used to proof lanes. If the
risk of live mines remaining in the lane does not exceed the risk of loss to
enemy fires while waiting, proofing may not be practical. Some mines are
resistant to some breaching techniques (for example, magnetically fused
mines may be resistant to the Ml CL I C blast), so proofing should be done when
theti me available, thethreat, and the mission allow.

During a limited clearing operation, proof upgraded breach lanes following a
breach. After the minefield is completely cleared, proof the routes used
through the area.

This section implements STANAGs 2036 and 2889.

This section provides commanders with a standard system for marking breach
lanes and bypasses. It centers around a systematic, phased upgrade of lane
marking. Each upgrade conforms to the tactical requirements for that phase

10-24 Minefield Reduction

C2, FM 20-32

of the attack, from initial reduction of the obstacle to the passage of larger
follow-on forces, as well as the return traffic necessary to sustain the force.
Additional guidelines are discussed in FM 3-34.2.

Marking breach lanes and bypasses is critical to obstacle reduction. Effective
lane marking allows the commander to project forces through the obstacle
quickly, with combat power and C 2 . It gives the assaulting force confidence in
the safety of the lane and helps prevent unnecessary minefield casualties.

There are two critical components of the lane-marking system:

• Lane-marking pattern (location of markers indicating the entrance,
the lane, and the exit).

• Marking device (type of hardware emplaced to mark the entrance, the
lane, and the exit).

The lane-marking system outlined in this section centers around standardized
marking patterns rather than the marking device. Standardizing the marking
pattern is critical to offensive operations. A common lane pattern—

• Enables cross attachments and adjacent units to recognize breach
lanes easily with minimal knowledge of a particular unit's tactical
SOP.

• Gives all forces a standardized set of visual cues that are needed to
pass through a lane safely while maintaining their momentum.

• Facilitates quick conversion to the lane-marking requirements of
STANAGs 2889 and 2036 (discussed later in this chapter).

The standard lane-marking hardware is decided by unit commanders. This
gives units greater flexibility and allows them to adopt marking devices that
are tailor-made for their type of unit and operational focus (such as an
armored or light force, a mounted or dismounted attack, limited visibility,
thermal capability). However, regardless of the type of device used, it must
support the standard lane-marking pattern outlined in the following
paragraphs. Therefore, commanders should consider these guidelines and
examples before developing or adopting their own marking system.

Lane-Marking Terms

The definitions in the following paragraphs provide a common basis for
discussing lane marking.

E ntrance Markers

Entrance markers indicate the start of a reduced lane through an obstacle.
They signify the friendly-side limit of the obstacle and the point at which
movement is restricted by the lane width and path. Entrance markers are
placed to the left and the right of the entrance point and spaced the width of
the reduced lane. They must be visually different from handrail markers to
help the force distinguish this critical point in the lane.

Handrail Markers

Handrail markers define the lane path through the obstacle and indicate the
limits of the lane width. As a minimum, mounted and dismounted lanes will

Minefield Reduction 10-25

FM 20-32

Exit Markers

have a left handrail marker. Mounted and dismounted forces moving through
the lane should keep the left handrail marker immediately to their left. As the
operation progresses, lane marking may be upgraded to include left and right
handrail markers.

Exit markers indicate the far side of the reduced lane through an obstacle.
Like entrance markers, exit markers must be distinguishably different from
handrail markers; however, the exit may be marked the same as the entrance.
Exit markers are placed to the left and the right of the exit point and spaced
the width of the reduced lane. This visual reference is critical when only the
left handrail is marked. The combination of entrance markers, left handrail
markers, and exit markers provide the driver and the tank commander with
visual cues so that they can safely pass through a reduced lane.

Entrance Funnel Markers

Entrance funnel markers augment entrance marking. The V formed by a
funnel marker forces the platoon into a column and helps drivers and tank
commanders make last-minute adjustments before entering a lane.

Final-Approach Markers

Final-approach markers are highly visible, robust markers that augment the
visual signature of entrance funnel markers. They are critical when initial
assault forces must maneuver to the breaching site. Normally, the initial
assault force can observe the breaching area but cannot clearly distinguish
entrance funnel markers. Final-approach markers provide the assault force
commander with a highly visible RP toward which to maneuver his formation.
They also signal company team commanders to begin changing from combat
column to column formation, with platoons in combat column.

Far Recognition Markers

Far recognition markers are highly visible markers that are located between
the final-approach marker and the friendly unit. They are primarily used
when passing forces are denied direct observation of the final-approach
marker due to distance, visibility, or terrain. When possible, far recognition
markers should be different from the final-approach marker. Far recognition
markers indicate the point at which forces begin changing their formation to
posture for the passage. A single far recognition marker may serve up to two
initial breach lanes. Once lanes are upgraded to two-way traffic, far
recognition markers are required for each two-way lane. When a far
recognition marker serves more than one lane, a guide or a traffic-control post
(TCP) is collocated with the far recognition marker that is nearest to the
breach.

Guides and Traffic-Control Posts

A TCP or a guide consists of a two-man team with communications means.
The team assists the commander in controlling the movement of forces. When
possible, military police (MP) should man TCPs. However, the commander
may initially use other personnel as guides to man critical far recognition
markers until the MP establish full TCPs. TCPs and guides provide the
commander with a man on the ground who controls traffic flow to the

10-26 Minefield Reduction

C2, FM 20-32

appropriate lanes. When there are multiple lanes branching off a single far
recognition marker, the TCP can assist in breaking parts of the formation off
into various lanes. The TCP can also help modify the traffic flow when lanes
have been closed for maintenance, for lane expansion, or by enemy
SCATMINEs. The guide or TCP must give the assault force commander the
azimuth and distance to the final-approach marker, identify the device used
for the final-approach marker, and provide the level of the lane-marking
pattern. For light forces, guides may physically escort passing units from the
far recognition marker to the lane entrance.

Levels of Lane Marking and Patterns

The three standard levels of marking for breach lanes and bypasses are
initial, intermediate, and full.

Each lane-marking level provides an increase in lane signatureand capability.
Lane requirements change as a breaching operation matures from an initial
breach to the forward passage of large combat forces.

I nitial lane-marking requirements are driven by the nature of the fight
through the obstacle. M arking must be rapid, providing only the bare
minimum signature needed to pass small units who make up the initial
assault force. This contrasts with the lane requirements of later phases of an
offense where larger units are passed to subsequent objectives. Here, the lane
signature must be more extensive and more visible, because it must guide
larger forces over a greater distance to the lane's entrance without
interruption. Two-way traffic becomes a priority for the simultaneous forward
passage of combat units as well as the return traffic (such as ambulances and
empty supply vehicles) that is necessary to sustain the force. Lane-marking
limits must be absolutely clear to the most inexperienced driver or crewman.
A fully developed lane must support two-way traffic and be completely
marked.

Bypasses are not marked the same as lanes. They are marked with directional
panels indicating the direction of the bypass. The limits of the mine threat
must be marked to prevent friendly forces from entering the minefield.
Marking the direction of the bypass and the minefield limits will enable the
maneuvering element to bypass the minefield without having to unnecessarily
defilethrough a marked lane. Further information on bypass marking can be
found in FM 3-34.2.

Commanders must be aware of how the needs of the force change with the
operation so that they can anticipate lane-marking and lane-capability
requirements. I ntegrating the levels of lane marking into the overall
breaching plan ensures that the unit's needs are satisfied. Forces necessary to
mark, maintain, and upgrade lanes must be allocated and tasked with the
mission. The phases of the scheme of maneuver and the service-support plan
are the basis for analyzing lane requirements. The following paragraphs
describe lane-marking patterns in detail and provide guidelines on when the
commander should upgrade lane marking and lane capability.

Initial Lane Marking

I nitial lane marking (Figure 10-22, page 10-28) is emplaced by the breach
force immediately after the lane is reduced and proofed. It provides a signal to

Minefield Reduction 10-27

C2, FM 20-32

the assault force commander that the lane is ready for traffic. I nitial lane
marking is kept to a minimum, centering on markings needed to pass
immediate assault forces through the lane to seize the initial foothold on the
objective. Normally, the assault force can observe the breach and does not
need the more visual signature of a mature lane marking. The initial lane-
marking pattern has the following markers:

Entrance.

Exit.

Left handrail.

Entrance funnel.

Final-approach.

The distance between markers is
driven by METT-TC. Distances
shown are a recommendation.

4.5 m (1 m*)
@ + ► @ Exit markers

O
O

Left-handrail markers

o

o

, 15 m (5 m*)

15m

(4.5 m*)/ '

O

4.5 m (1 m*)
@ -< ► @ Entrance markers

200 m (30 m*)

A

Entrance-
funnel
markers

Final-
approach
marker

'Distance for dismounted lanes

Figure 10-21. Initial lane marking

10-28 Minefield Reduction

FM 20-32

The entrance, left handrail, and exit markers are the first markers emplaced
by the breach force because they define the location and the limits of the
reduced lane.

• Entrance markers are placed to the left and the right of the reduced
lane's entrance point, and they are spaced the width of the lane (4.5
meters for mounted lanes, 1 meter for dismounted lanes).

• Left handrail markers are placed at the left limit of the lane, along the
entire path. Handrail markers are placed at 15-meter intervals for
mounted forces and at 5-meter intervals for dismounted forces.
Commanders may have to modify the intervals based on the terrain,
the visibility, the lane length, and the lane path.

• Exit markers are placed to the left and the right of the reduced lane's
exit point, and they are spaced the width of the lane (4.5 meters for
mounted lanes, 1 meter for dismounted lanes).

Once the entrance, left handrail, and exit markers are emplaced, the breach
force emplaces the entrance funnel markers and the final-approach marker.

• Entrance funnel markers are placed at 15-meter intervals for
mounted forces and at 5-meter intervals for dismounted forces. They
are placed diagonal to the lane entrance and form a 45-degree V
(Figure 10-22).

• The final-approach marker is centered on the lane and placed at least
200 meters from the lane entrance for mounted forces. For dismounted
forces, the nature of the attack may initially preclude using a final-
approach marker; however, as soon as the mission allows, a final-
approach marker is placed 30 meters from the entrance. Final-
approach markers for mounted and dismounted forces must be placed
on high ground to ensure that they are clearly visible. The commander
may modify the recommended distance for the final-approach marker,
based on the terrain and the visibility.

Intermediate Lane Marking

Upgrading initial lane marking to intermediate lane marking (Figure 10-23,
page 10-30) is triggered by one of two key events— the commitment of larger
combat forces who are unable to directly observe the breach or the rearward
passage of sustainment traffic (casualty evacuation and vehicle recovery).
I ntermediate lane marking has two goals:

• Increasing the lane signature to help the passage of larger, more
distant combat forces.

• Providing sufficient marking for two-way, single-lane traffic.

I ntermediate lane marking builds on initial lane marking by adding right
handrail markers, exit funnel markers, far recognition markers, and a farside
final-approach marker.

The commander sets the priority of marker emplacement based on the
situation. I f the scheme of maneuver requires the immediate passage of larger
combat forces, the right handrail markers and the far recognition marker may
be the priority. On the other hand, if it is necessary to ground evacuate
casualties or to recover vehicles, emplacing right handrail markers, exit
funnel markers, and a farside final-approach marker may be required first.

Minefield Reduction 10-29

C2, FM 20-32

The distance between markers is
driven by METT-TC. Distances
shown are a recommendation.

Exit-funnel
markers

Farside final-
approach marker

200 m (30 m*

4.5 m (1 m*)
@ « ■ ►

O

O

Exit markers

o
o

Left-handrail q q Right-handrail

markers Tl5m(5m*) markers

O O

700 m (230 m*)

A

•Distance for dismounted lanes

15 m

o
o

4.5 m (1 m*)
@ + ►

200 m
(30 m*)

O
O

Entrance markers

Entrance-
• funnel

_ markers

Final-
approach
marker

Far-recognition
marker

P

500 m (200 m*)

Guide or TCP

Figure 10-22. Intermediate lane marking

When upgrading to intermediate marking, the first step is to emplace the
right handrail markers. Right handrail markers define the rightmost limit of
the lane. They are placed the width of the lane as defined by the entrance and
exit markers. The right handrail follows a path parallel to the left handrail
through the obstacle. Right handrail markers are placed at the same interval
as left handrail markers.

Exit funnel markers and a farside final-approach marker are emplaced to
mirror the entrance markers. Exit funnel markers prevent the premature
deployment of the passing force into combat formation before it is safely

10-30 Minefield Reduction

FM 20-32

outside the obstacle. They also become the entrance funnel markers for
rearward passing traffic, giving these forces the visual cues needed to line
themselves up on the lane. The exit funnel markers are augmented by a
farside final-approach marker to help rearward passing forces clearly identify
the lane from their side. The farside final-approach marker is centered on the
lane and placed 200 meters (mounted forces) or 30 meters (dismounted forces)
from the exit.

A far recognition marker completes intermediate lane marking. It provides
commanders with a visual signature or a series of signatures for guiding their
movement toward the lane. For mounted forces, the far recognition marker
nearest to the breach lane is placed 500 meters from the lane entrance or on
the nearest terrain feature. Dismounted forces may require a system of guides
instead of far recognition markers for passing combat forces; however, far
recognition markers must beemplaced as soon as possible to reduce guide
requirements for passing mounted sustainment traffic. This gives the assault
force commander the space needed to transition his formation to companies in
combat column. Far recognition markers may be emplaced before or
concurrent with exit markers, based on the mission and the situation.

The commander collocates guides or TCPs at the far recognition marker when
he feels the situation requires more positive control over traffic flow.
Commanders should plan for the use of full-time guides once they have
upgraded to intermediate marking. TCPs become mission-critical during
limited visibility or in restrictive terrain. They should also be used when a
single far recognition marker feeds more than one breach lane. TCPs must be
manned with a minimum of two soldiers and must have FM communications
with the control ling headquarters. It is essential that soldiers acting as guides
or TCPs know the—

Azimuth and distance to the breach lane and the 8-digit grid
coordi nate of the lane.

Level of lane marking.

Type of final-approach marker used.

Traffic-control plan and march order.

Up-to-date status of lane marking, maintenance, and so forth.

Full Lane Marking

Expanding breach lanes to full (two-way) lane marking (Figure 10-24, page
10-32) is resource-intensive and is not normally a part of an initial breach
operation. A fully matured lane is one that will support uninterrupted, two-
way traffic. Expanding a breach lane to a full lane involves expanding the
width of the lane to accommodate two-way traffic and modifying the marking
pattern to give forward and rearward passing forces the same visual
signature. Upgrading to a full lane is normally assigned to follow-on engineer
forces, since it is usually beyond the immediate capability of engineers with
forward units.

U pgrading intermediate lane marking to full lane marking begins by
temporarily closing the lane, rerouting traffic, and expanding the lane width.
The initial reduced and proofed lane is always expanded to the left, in relation
to the direction of the attack. Engineers reduce and proof the obstacle
beginning at the left handrail togivea total lane width of 10 meters (5 meters

Minefield Reduction 10-31

C2, FM 20-32

Guide or TCP

The distance between markers is ^^^_
driven by METT-TC. Distances
shown are a recommendation.

Far-recognition
marker

Return 1 1 1
traffic ▼

• |

Final-approach
marker

•

Funnel
markers £

•
•

Left handr
forward ar
traffic

©

@ Entrance/exit markers

311 TOT 4

id return — -^^^ „

10m
O ,

* O

O
Right handrail
(return traffic) O

o
o

O .Original lane

Right handrail
O (forward traffic)

O

o

O

o ■

' o

O

©

©

@ Entrance/exit markers

A

Funnel £
markers

•

10 m

•

A •

#

m \ Final-appr
/ \ marker

oach
lition

im.

O

<

Far-recog
marker

' | ' Forward
1 traffic

■

G

jide or TCP

Figure 10-23. Full lane marking

each way). The expansion width requirement is the same for armored and
light forces, because both forces must be able to pass mounted sustainment
and combat forces during this phase.

Once the engineers expand the lane width to 10 meters, they ensure that
entrance, exit, handrail, funnel, and final-approach markers are replaced on
the return lane. All markings are the same as described in previous
paragraphs.

The full lane-marking pattern has three entrance and three exit markers.
They are placed the width of forward and return lanes and are visually
different from other markers. Units must be trained to recognize that three
entrance markers indicate a two-way traffic lane and that they should always
use the rightmost lane.

10-32 Minefield Reduction

C2, FM 20-32

Entrance and exit funnel markers are placed slightly different from previous
marking patterns. They extend out from the entrance and exit markers on the
right side only.

Final-approach markers are placed 200 meters from, and centered on,
entrances of forward and return lanes. This helps forces clearly identify the
entrance points from either direction.

Far recognition markers are placed a maximum of 500 meters from the lane
entrance or on the nearest terrain feature from forward and return final-
approach markers.

Commander's Guidance for Lane Marking

Table 10-1 provides a summary of lane-marking levels, guidelines on unit
responsibilities, and events that trigger lane upgrade. I n thetable, who refers
to the unit responsible for lane upgrade marking and when describes events
that trigger the need to upgrade.

Table 10-1. Lane-marking levels, unit responsibilities, and trigger events

Initial

Intermediate

Full (Two Way)

Who

TF breach force

TF breach force

Brigade

When

Obstacle is reduced

Passing battalion- or
company-size forces

Passing brigade- or battalion-size
forces

Passing platoon- or
company-size assault forces

Passing force which
cannot see the lane

Situation requires uninterrupted
sustainment traffic

Passing TF combat
trains

Markers

Entrance

Add right handrail

Expand lane width to 10 meters

Exit

Add exit funnel

Adjust entrance/exit

Left handrail

Add farside final
approach

Adjust left/right handrails to new width

Entrance funnel

Add far recognition

Add far recognition

Final approach

Add guides or TCPs

Add farside guides or TCPs

Minefield Reduction 10-33

FM 20-32

Lane-Marking Devices

The majority of lane marking in the field is done by using nonstandard
marking devices. When adopting a nonstandard marking device, commanders
should consider the guidelines summarized in Table 10-2.

Table 10-2. Guidelines for lane-marking devices

Marker

Mounted Forces

Dismounted Forces

Handrail and funnel
markers

Visible by TC and driver
(buttoned up) from 50 meters

Visible by a dismounted soldier in
a prone position from 15 meters

Quick and easy to emplace,
minimizing the need to expose
soldiers outside the carrier

Lightweight, quick, and easy to
emplace (a dismounted soldier
should be able to carry enough
markers for the lane and still be
able to fire and maneuver)

Entrance and exit
markers

Visible by TC buttoned up from
100 meters

Visible by a dismounted soldier
from 50 meters

Visually different from handrail
and funnel markers

Visually different from handrail
and funnel markers

Quick and easy to emplace (may
require soldiers to dismount to
emplace)

Lightweight, quick, and easy to
emplace

Easily man-portable

Final-approach and
far recognition
markers

Visible by TC (not buttoned up)
from 500 meters

Visible by a dismounted soldier
on the march from 100 meters

Visually different from each other

Visually different from each other

Visually alterable to facilitate
traffic control through multiple
lanes

Visually alterable to facilitate
traffic control through multiple
lanes

Figure 10-25 shows some of the devices that can be utilized for lane marking,
and they are easily procured or fabricated. This is not an inclusive listing but
is intended to show commanders some of the options.

Some general requirements for lane marking are—

• Markers must be able to withstand the rigors of the terrain, the
weather, and the battlefield.

• Markers should be easy to modify, using minimal manpower and
equipment, when visibility is limited.

• Lane-marking panels should have thermal and I R reflective marking
so that they can be easily identified during limited visibility.

• Enhancements for limited visibility should be a constant source rather
than a pulsating strobe. Strobes do not make the marking pattern
readily apparent, particularly when approaching from an angle.

10-34 Minefield Reduction

FM 20-32

C^>

Traffic cone

Highway marker

Tippy Tom

T

HEMMSpole

NOTE: Cut 61 cm
above the base to
make a short pole.

61 cm

HEMMSpole

p inel str

7 6,

^

Short pole

N

10 cm

Stake
straps

LP

Base
Y plate

26cm

ShoTPpole
assembly

NOTE: Stack 3
short poles to
make a long pole.

ten

Long-pole
assembly

Exit marker

li'''-"> handrail

w

marker

Entrance
Vmarker

i
i

VS-17

panel

Ju->

R

Far recognition marker
using camouflage
support system

Figure 10-24. Marking devices

Minefield Reduction 10-35

FM 20-32

The following standard marking sets are available through normal supply
channels:

• Minefield marking set number 2, line item number (LIN): M49096,
NSN: 9905-00-375-9180.

• HEMMS, LIN:M 49483, NSN: 9905-01-019-0140.

Marking Requirements of the North Atlantic Treaty Organization

The following paragraphs paraphrase the lane-marking requirements
outlined in STANAGs 2889 and 2036. They also establish the procedures used
by US forces to modify intermediate and full lane marking to STANAG
standard. With the combined nature of warfare, commanders need to be aware
of their responsibilities for marking hazardous areas, particularly breach
lanes.

STANAGs 2889 and 2036 state that the type of marking device, pattern, and
lighting used to mark breach lanes in forward areas is at the discretion of
national authorities or the authorized commander. This gives commanders
who are participating in a combined operation the flexibility to mark lanes
consistent with their respective Army's standard. It also outlines minimum
requirements for the lane-marking pattern before it is used by troops of other
nations; however, commanders must plan for converting a lane to NATO
standard as early as possible. When converting to NATO standard, the
STANAG directs commanders to use lane-marking devices as stated below.
Within an offensive operation, marking a lane to NATO standard will not
normally occur until after the lane is matured to a full lane.

Marking Pattern and Device

The intermediate lane marking discussed earlier satisfies the minimum lane-
marking pattern that must be used before forces from another country are
able to pass through a lane. STANAGs 2889 and 2036 state that regardless of
the marking device used, the entrance point, exit point, and left and right
handrails are the minimum required lane signature. Therefore, once the lane
is marked to the intermediate level, allied forces can use the lane without any
additional marking.

STANAG 2889 requires that commanders convert marking devices to NATO
standard as early as possible. Figure 10-26 shows a NATO standard marker.
The marker is placed at right angles to the direction of travel, so that the
white portion of the arrow points inward tothelane, indicating the safe side of
the lane. The red portion is outward, indicating the lane limit or dangerous
side of the lane. STANAG 2889 also requires that markers be large enough to
be visible from 50 meters under most daylight conditions and have a field life
of 60 days.

Conversion to NATO Standard Marking

Toconvert intermediate and full lane marking to NATO standard, affix NATO
markers to long pickets and replace the existing entrance, exit, funnel, and
handrail markers one for one (Figure 10-27).

Two NATO markers are used for entrance and exit markers to make them
distinctly different. One NATO marker is affixed to each funnel marker and to

10-36 Minefield Reduction

C2, FM 20-32

Lane markers painted red and white are erected at intervals of
about 30 meters from the lane entrance to the exit.

t"H

(Red)

W

(White)

HM

(White)

Lane

lAV

(Red)

Markers must be placed at right angles to the direction of the lane.

Figure 10-25. NATO standard marker

Illuminated wheel or track
sign fixed beneath route
markers (see Note 5)

WN

Guide sign

2.

NOTES:

1. Minimum lane width = 4.5 m

Normal one-way lane width = 8 m
Normal two-way lane width = 16 m

The use of separate track and wheel
routes and the distance of the route
junction from the lane is a decision
for the tactical commander.

The marking interval within the lane
should be 30 m.

On separate routes for wheeled and
tracked vehicles, the appropriate
yellow and black illuminated sign
may be fixed beneath the route
marker.

Route
I markers

nn>

T30m

5.

Only approach and exit markers are
required.

Black
Yellow

unw

r<BHJ Ent /? n h c t e/

exit lights

Lane

Route markers

(IQ[ J Entrance/
\^ exit lights

Illuminated wheel or
track sign fixed
beneath route
markers (see Note 5)

Guide sign

Figure 10-26. NATO lane-marking conversion

Minefield Reduction 10-37

C2, FM 20-32

each left and right handrail marker. When converting full lane marking, the
center handrail is marked with a modified NATO marker. The combination of
a modified center handrail marker and directional arrows at each lane
entrance provides allied forces with the signature necessary to distinguish
two separate lanes. I n addition, a barbwire or concertina fence (one strand
minimum) is laid 1 meter above the ground to connect funnel markers,
entrance markers, handrail markers, and exit pickets.

NATO uses whiteor green lights to illuminate markers at night (Figure 10-28).
Entrance and exit markers are marked with two green or white lights placed
horizontally, so that the safe and dangerous markings on them are clearly
visible. One whiteor green light is used on funnel and handrail markers. The
commander decides whether the light is placed on top of the NATO marker or
placed so that it illuminates the markers. Lights must be visible from a
minimum of 50 meters under most conditions and have a continuous life of 12
hours.

(Red)

(White)

(Red)

Lights (green
or white)

Exit
markers

Lights (green
or white)

Lane
markers

Lights (green
or white)

Entrance
markers

(White)

(Red)

(White)

(White)

(Red)

Figure 10-27. NATO standard marking for limited visibility

The mission toconvert intermediate or full lane marking to NATO standard is
normally assigned to corps-level engineer battalions working in the division
rear area. In special cases, divisional engineer battalions may be tasked with
NATO marking.

10-38 Minefield Reduction

C2

Chapter 11

Route and Area Clearance

The ability to move forces and material to any point in an AO is basic to
combat power and often decides the outcome of combat operations.
Maneuver relies on the availability of LOC within an AO; and during
OOTW, clear LOC is essential to the movement of forces. Units must
conduct route and area clearance to ensure that LOC enables safe passage
of combat, combat support (CS), and CSS organizations. Clearance
operations are best-suited for rear-area and stability support operations.

ROUTE CLEARANCE

Route clearance is a combined arms operation. Units must clear LOC of
obstacles and enemy activity that disrupt battlefield circulation.

Planning

Intelligence

Fundamentals

Organization

The principles of breaching operations (Chapter 9) apply to the development
and execution of the route-clearance mission. The breaching tenets
(intelligence, fundamentals, organization, mass, and synchronization) should
be the basis for planning.

I ncorporating the I PB and M ETT-TC factors into route-clearance operations
will enable units to predict what the enemy will do and where it will do it. The
IPB and the EBA offer ideal methods for establishing a SITE MP. After the S2
and the engineer identify the most probable threat sites, theS2 designates
them as N Al s. These N Al s are the focus of the reconnaissance effort.
Engineers work in concert with other reconnaissance assets to confirm the
presence or absence of ambushes, UXO, and minefields. The information
gathered from the IPB and the reconnaissance effort determines the method
and the type of route clearance necessary. It also helps the commander
determine any outside resources (EOD, SOF) that he may need.

SOSR may not be executed, but it is planned as it is in breaching operations.
Units must be prepared to execute SOSR fundamentals as necessary.

Task organization for a route clearance is similar to the task organization for
a deliberate breach. The clearance company team is organized into breach,
support, and assault forces. The breach force conducts clearing operations, the
support force isolates the area being cleared, and the assault force performs
security functions beyond the clearance site (traffic control points) and assists

Route and Area Clearance 11-1

FM 20-32

the breach force in disengagement, as required. Table 11-1 shows a sample
task organization for a route clearance.

Table 11-1. Sample task organization for a route clearance

Team

Support Force

Assault Force

Breach Force

Heavy

Mechanized infantry
platoon with
dismount capability
• Armor platoon

• Mechanized infantry platoon

• Engineer squad

• Mortar section

• Medical team (two ambulances)

• PSYOP team

• FIST

• MP element

Engineer platoon with
organic vehicles
• Armor platoon with
plows and rollers

Light/Heavy

Two infantry platoons
(light)

• Bradley platoon with dismount
capability

• Engineer squad

• 60-mm mortar section

• Medical team (two ambulances)

• PSYOP team
Forward observer

• MP element

• Engineer platoon with
organic vehicles

• Armor platoon with
plows and rollers

Light

Two infantry platoons
(light)

• AT/MP section with M60/MK1 9 mix

• 60-mm mortar section

• Medical team (two ambulances)

• PSYOP team
Forward observer

• MP element

• Engineer squad (+)

• Infantry platoon (light)

• AT/MP section with
M60/MK19mix

Mass

Sufficient maneuver and engineer assets must be allocated to the clearance
company team. The length and the width of the route and the type of
clearance to be conducted determine the size of the sweep team. Clearing a
Class A military road with the deliberate sweep technique requires at least
two engineer squads due to the total lane width to be cleared and the
requirement for the rotation of mine-detector operators. Depending on the
type of sweep operations, the commander can expect a 50 percent loss of sweep
assets. Normally, as in breaching, a 50 percent redundancy of engineer assets
should be allocated to the sweep team.

Synchronization

All aspects of synchronization should be implemented when planning route
clearance. It is especially important that rehearsals be conducted at the
combined arms level. Rehearsals should include—

• Reaction to enemy contact.

• Reaction to an ambush.

• Communications exercise.

Fire support (obscuration smoke, immediate suppression fires, critical
friendly zones for counterfire radar, and no-fire area around the
clearance site).

11-2 Route and Area Clearance

FM 20-32

CSS (maneuver, casualty evacuation, marking materials, and
demolitions resupply).

Planning Considerations

Intelligence

Maneuver

The purpose of breaching is to project combat power to the farside of an
obstacle, and breaching usually occurs under enemy fire. Route-clearance
operations focus on opening and maintaining LOC to ensure the safe passage
of combat, CS, and CSS organizations. Like breaching, route-clearance
operations require extensive BOS coordination. The following planning
considerations should be used by brigade and battalion TFs when planning
route-clearance operations:

• Identify choke points, bridges, tunnels, critical road junctions, and
other built-up areas. These are the most suspect areas for obstacle
emplacement. However, depending on the enemy's overall mission, it
may not always empl ace obstacles at these locations. This is especially
true if the enemy's goal is to psychologically disrupt our convoys.

• Maintain a situation map with a graphics overlay that reflects the
most current intelligence information.

• Maintain an incident map with a graphics overlay to facilitate a
pattern analysis.

• Maintain a threat order-of-battle database, such as how the enemy
will disrupt unit LOC.

• Develop a detailed R&S plan that incorporates modern battlefield
techniques and systems, such as ground sensors, forward-looking
airborne radar, and satellite images. As a minimum—

— Coordinate for UAV support, if available.

— Develop infiltration routes to support recon and security at likely
enemy ambush sites.

— Develop an estimate of impact to civilians on the battlefield
(COBs). COBs include local nationals, nongovernment
organizations (NGOs), and private volunteer organizations
(PVOs).

— Conduct a daily flight over the area to provide up-to-the-minute
intelligence. When available, coordinateASTAMIDS coverage.

— Coordinate with the USAF to periodically check the route (for
example, using an AC-130 Specter gunship).

• Provide an intelligence update to company team leaders before
departure. This should be in the form of a 1:50,000 enemy SITEM P
overlay (confirmed and suspected/tempi ated).

• Establish liaison with the host nation, NGOs, and SOF.

• P rovi de person nel f or TC P s.

Route and Area Clearance 11-3

FM 20-32

Fire Support

Clear and secure flanks (at least 100 meters) and the farside of
suspected and known obstacle locations.

Close the route to US-controlled traffic during route-clearance
operations to minimize the target presented to enemy forces.

Identify and clear potential sniper positions before beginning obstacle
reduction or clearance.

Provide security for the cleared route.

Give operational control (OPCON) of aviation assets to the route-
clearance commander for clearance-support missions.

Plan the building of static security points along the cleared route to
reduce the probabi I ity of reseedi ng.

Plan smokefor tempi ated locations.

Position mortars to ensure continuous coverage of the operation (move
and set up with the support force).

Preparefires within the tactical rules of engagement.

Ensure that the route-clearance team has a FIST coordinator. The
clearance commander should locate the FIST element well forward in
the order of march.

• Designate obstacle clearance sites as critical friendly zones for
counterfire radar and no-fire areas.

NOTES:

1. Priority targets shift in conjunction with company team movement
on the main supply route (MSR).

2. Clearance of fires is the responsibility of the maneuver commander
of the sector where the target is located.

3. Adequate Q-36 radar coverage is necessary for deliberate sweep
operations.

Mobility/Survivability

Provide detailed OBSTI NTEL on minefields. It must include the—

— Description of mines or explosive devices most likely encountered.

— Composition and pattern of obstacle(s).

— Enemy actions or techniques used during obstacle emplacement.

Conduct deliberate sweep operations 100 meters past the obstacle or
suspected threat.

Report, clear, and mark mines, obstacles, and explosive devices to
facilitate unimpeded movement.

Ensure that lane marking meets the standards outlined in Chapter 10
and that materials and techniques are standard throughout the route.

11-4 Route and Area Clearance

FM 20-32

Consider including road repair equipment and material as part of the
sweep element (for example, a 5-ton dump truck filled with soil and an
ACE to spread the soil).

Keep all radios, electronic equipment, and aviation assets at a safe
distance during reduction operations.

Block uncleared roads and trails that branch from the route being
cleared. This protects units from inadvertently traveling an uncleared
route.

Debrief the chain of command and the TF S2 on the location, the
composition, and the orientation of all obstacles cleared and
encountered. This assists the S2 and the engineer in IPB/EBA pattern
analysis.

Air-Defense Artillery

• Consider the possibility of an air attack.

• Use the following passive air-defense measures:

— Eliminate glare by using mud, tape, cardboard, or camouflage nets
to cover headlights, mirrors, and portions of windshields.

— Reduce dust clouds by reducing speed.

— Plan routes that offer natural concealment.

— Use air guards.

• Increase the distance between vehicles.

• Incorporate Stinger missileteams into the support force.
Combat Service Support

• Ensure that clearance operations are supported by a logistical/combat
health support (CHS) package from the brigade support area.

• Plan for air and ground evacuation of casualties. The preferred
evacuation method is by air; the routine method is by ground.

— Conduct an air-mission brief with air ambulance assets, to include
pickup zones and markers. Rehearse procedures for evacuation
requests.

— Ensure that the medical team consists of one or two ambulances.
Locate the medical team with the support force.

— Identify the ambulance exchange point along the route to be
cleared.

• Ensure that all personnel wear flak vests or I BASIC (Figure 11-1,
page 11-6).

• Ensure that all vehicles have tow cables in the front and the rear for
extraction purposes.

• Ensure that all vehicles carrying troops have hardening (sandbags on
floors and sides).

Route and Area Clearance 11-5

C2, FM 20-32

SPECS

Antifragmentation
protective trousers

AP overboots

Figure 11-1. IBASIC

Provide MP and explosive-sniffing dogs to help in clearance and
provide security for convoys during and after clearing operations.

Command and Control

NOTE : The company team commander is required to operate on three
separate frequencies— battalion command network, company team
command network, and fire-support network.

• Designate, recognize, and include minefield indicators (Chapter 10) as
part of company team rehearsals.

• Designate a reserve force (at least platoon-size) that is mechanized or
air-assault capable.

• Ensurethat proper rehearsals are planned and conducted according to
FM 3-34.2. As a minimum, the clearance force should rehearse actions
on the obstacle, actions on enemy contact, casualty evacuation, and
the control of COBs.

• Ensurethat the tasked unit has a clear understanding of the mission,
intent, and end state. For example, the clearing unit commander
should understand that his unit must clear the road width, including
the shoulders, and secure the route.

• Assign clearance responsibilities to brigade and battalion assets.

• Ensurethat the maneuver commander/TF S3—

11-6 Route and Area Clearance

Special Operations

FM 20-32

— Controls the movement of all personnel and equipment along the
route (travel authorization is coordinated through the S4).

— Prepares a mine risk assessment of the mission before issuing the
OPORD. (An example of a mine risk assessment is shown in
Appendix F.)

— Tracks the status of routes (red, amber, green) in the TF sector,
based on the amount of time since the route was cleared and the
intelligence and enemy situations.

— Tracks the progress of the clearance operation and integrates it
into the maneuver and CSS plans.

— Determines the route length, using clearly definable start and end
poi nts.

— Sets priorities for the route-clearance element.

— Coordinates with adjacent units, the host nation, NGOs, PVOs,
andSOF.

Ensure that psychological operations (PSYOP)/civil affairs (CA)
support the counterintelligence effort by conducting civilian
interviews.

Direct civilians along the MSR to the displaced-personnel holding
areas or along the routes that the brigade has indicated for use.

Employ PSYOP/CA teams forward to disperse civilians and provide
traffic management to isolate the route during clearance operations.

Task Organization

Support Force

Assault Force

A brigade or battalion TF normally conducts clearance-in-zone operations. To
clear a route, the battalion TF focuses a company team as the main effort on
the proposed MSR. Table 11-1, page 11-2, shows a sample task organization
for a route clearance.

This force is comprised of two maneuver platoons and the maneuver company
team XO. The support force provides flank security, rear security, and
protection to the breach force. It neutralizes hostile forces encountered by the
company team. In rugged terrain or highly mined areas, moving the assault
force on the flanks would be too risky. Aviation assets can provide flank
security while ground forces provide rear security. The assault force also
searches for suspected off-route mines.

This force is comprised of a maneuver platoon, an engineer squad, a mortar
section, a medical team, a PSYOP team, an EOD team (or one that is on call),
and a forward observer. The assault force's mission is the same as in a
breaching operation (Chapter 9).

Route and Area Clearance 11-7

C3, FM 20-32

Breach Force

This force is comprised of a maneuver platoon (including the commander) and
an engineer platoon (minus). The breach force sweeps the route and reduces
mine and explosive threats. It is further task-organized into sweep teams.

A sweep team is a trained detection team that searches for mines and
explosive devices. The organization of the sweep team depends on the type of
sweep mission and the length, the width, and the surface composition
(pavement, gravel, dirt) of the area to be swept. A platoon-size element can
normally clear a 4.5-meter-wide path, and a squad-size element can normally
clear a 1.5-meter-wide path. If the route is wider or time does not permit
multiple passes of the route, additional engineer assets are required. Table 11-
2 outlines personnel and equipment requirements for a sweep team.

Table 11-2. Personnel and equipment requirements for a sweep team

Personnel

Support Personnel

Equipment

• NCOIC

Medics

• One panel marker

Mine-detector

• Vehicle operator

• Operational map with required maneuver graphics

operators

Four smoke grenades (minimum)

Probers/markers

• Six mine detectors (includes three backups) and extra

• Radio operator

batteries

Demolition teams

• Two grappling hooks with 60 meters of rope each

• One demolition kit or bag for each demolition man

• Six probes

Mine marking material

• Lane marking tape

• Ten stakes

Platoon-Size Sweep Team

The normal configuration for a platoon-size sweep team is twelve soldiers in a
modified column (Figure 11-2). The platoon leader supervises the entire
operation. This configuration is best suited for sweeping routes in friendly
territory that is not under constant surveillance.

When sweeping in areas where 100 percent coverage is required, the team
should establish a clear lane from which to operate. This is conducted by the
grapple hook being thrown one additional time into the suspected minefield.
The cord on the grapple hook is pulled taunt, with the free end secured to a
stake.

This establishes a left or right physical boundary marker for the mine-
detector operator to use as a guide. The first mine-detector operator will
sweep a 1.5-meter lane left or right of this cord, up to the grapple hook. At the
hook, a second stake will be emplaced to hold the boundary line and the
grapple hook will be thrown again and pulled for trip wires as before. A fourth
throw will serve as the boundary marker through the suspected minefield.
This procedure will continue until the first mine-detector operator is out of the
minefield on thefarside.

The boundary marker will then be secured to stakes, using the lane marking
tape. A second boundary maker will be placed 1 meter to the left or right of the
original boundary marker, depending on which side was swept. This will

11-8 Route and Area Clearance

C3, FM 20-32

Subarea to be cleared

Subarea to be cleared

Mine-
detector
operator

Ol

en

m

(-)

Relief JeStST 6 "
Ri r aScp r / operators Radio NCOIC
-Jr) operator .-^

w (7) ( 5 ) Mine-

. X1Z _ _de_tecjoi_

Relief (O Demolition Prober/ operator

demolition \!y man marker ^^

man ( 3 )

Mine-
detector
operator

©"

en

50 m

30 m

10 m 30 m

30 m

30 m

Figure 11-2. Platoon-size sweep team

establish a fixed 1-meter lane. The 0.5-meter area that was not included in the
original lane is to ensure that no gaps in coverage were missed on the edge of
the first lane.

The unit will then stretch a piece of marking tape out from across the clear
footpath, moving it left or right 1.5 meters and staking it down on both ends.
This will be repeated as many times as necessary.

Always mark lanes that have not been cleared with a piece of marking tape
across the entry to that lane to prevent personnel from using the lane before it
has been swept. After multiple lanes are physically marked, the unit can
perform a platoon-size sweep. Lanes should be swept and cleared by working
out from the original 1-meter footpath. As the cleared area becomes bigger, the
marking tape is removed to allow the passage of personnel and equipment
though the cleared lane.

As subsequent lanes are being swept, the marking tape will need to be secured
on the outside edge of the lane. Always conduct a thorough sweep of the spot
where the stake will be placed. Stake intervals will depend on terrain and
atmospheric conditions.

Soldiers 1, 2, and 3 (mine-detector operators) lead the sweep team in echelon.
Each sweep team covers 1.5 meters of front, and sweep teams are spaced 30
meters apart to prevent fatalities from accidental detonation by other mine-
detector operators. If required, a fourth mine-detector operator can be added
to the detection column.

Soldiers 4 (NCOIC) and 5 (prober/marker) follow 30 meters behind the last
mine-detector operator (Soldier 3) and are centered in the cleared lane. The
prober/marker is responsible for marking the cleared lane on both sides.

Route and Area Clearance 11-9

C3, FM 20-32

Soldiers 6 (radio operator) and 7 (demolition man) follow 10 meters behind
Soldiers 4 and 5 and are centered in the cleared lane.

Soldiers 8, 9, 10 (relief mine-detector operators), 11 (relief prober/marker),
and 12 (reserve demolition man) follow 30 meters behind Soldiers 6 and 7. If a
fourth mine-detector operator is added to the column, an additional relief
mine-detector operator must also be added.

The remaining platoon members help the support force or act as a reserve
force, as required. They should first be integrated into the sweep team as a
relief element and then moved forward as needed.

Squad-Size Sweep Team

The normal configuration for a squad-size sweep team is seven soldiers in a
modified column (Figure 11-3). The squad leader supervises the entire sweep
operation. This configuration is designed for sweeping routes in friendly
territory that is not under constant surveillance.

Subarea to be cleared

Relief

prober/

marker

ai

Radio NCOIC
operator

Mine-
detector _
operaTor

Cleared area

Relief mine-
detector
operator

Demolition Prober/
man marker

en

30 m

10m

30 m

Figure 11-3. Squad-size sweep team

Soldier 1 (mine-detector operator) leads the sweep team and covers a 1.5-
meter-wide path.

Soldiers 2 (NCOIC) and 3 (prober/marker) follow 30 meters behind Soldier 1
and are centered in the cleared lane. The prober/marker is responsible for
marking the cleared lane on both sides.

Soldiers 4 (radio operator) and 5 (demolition man) follow 10 meters behind
Soldiers 2 and 3 and are centered in the cleared lane.

Soldiers 6 (relief mine-detector operator) and 7 (relief prober/marker) follow
30 meters behind Soldiers 4 and 5. If the squad cannot use seven team
members, the relief prober/marker position can be eliminated from the
formation.

The engineer platoon can configure the platoon into squad-size sweep teams
and placethem in echelon (Figure 11-4).

11-10 Route and Area Clearance

C3, FM 20-32

Subarea to be cleared ui

_ _ _ 3

Subarea to be cleared ui

en

ai

3rd squad 2nd squad 1st squad

Figure 11-4. Sweep teams in echelon

Methods and Types

The information gathered from the I PB and the reconnaissance effort
determines the method and the type of route clearance to conduct. The
determination is based on the situation, the time available, the threat level,
and available assets.

During OOTW, it is recommended that former warring faction (FWF)
engineer-equivalent clearance teams precede US forces clearance teams
within the FWF 's AO. Do not assume that FWF clearance teams will be
thorough in their clearance operation. Treat the route as unsafe until US or
allied force clearance teams have proofed the route to confirm that it is
cleared.

Methods

There are three methods of route clearance— linear, combat, and combined.
The method employed depends on the situation, the time available, and the
clearance assets available. The maneuver force should always establish static
security positions at critical locations following the completion of route
clearance.

Route and Area Clearance 11-11

C3, FM 20-32

Linear Clearance

I n linear clearance (Figure 11-5), sweep and security teams begin route
clearance at Point A and complete it at Point B. This method provides the best
assurance of route coverage. Although this is an effective method, it is not the
most secure method in a high-threat environment. It is also time-intensive
and constrains the maneuver commander's flexibility.

MSR WHITE

Sweep routes-

Figure 11-5. Linear clearance method

Combat Clearance

Whereas linear clearance focuses on a specific route, combat clearance
(Figure 11-6) focuses on specific points along a route. As mentioned previously,
IPB and EBA can identify areas for likely mine and ambush locations. These
areas become NAIs or objectives for combat clearance missions. The combat
clearance method divides a route into sections according to the number of
suspected high-threat areas. Once the sweep element (maneuver and engineer
forces) secures and sweeps these areas, the route is considered clear. Combat
forces can patrol the route from these objectives to ensure that the route is
secure, and if necessary, the sweep element can sweep the surrounding area if
a minefield is found. Following the seizure of these objectives, the commander
must assume a moderate risk that the S2 and the force engineer have
identified all high-threat areas and that the route is clear of mines. Combat
clearance is ideal for dismounted (light) forces since it provides the maximum
use of surprise and concealment.

11-12 Route and Area Clearance

C3, FM 20-32

MSR WHITE

Sweep '

Figure 11-6. Combat clearance method

Combined Clearance

Types

This method combines the complete clearance capabilities of the linear
clearance method with the security and surprise elements of the combat
clearance method. Combined clearance is a two-phase, force-intensive
operation and may require a battalion-size effort, depending on the length of
the route. First, identify high-threat areas through IPB/EBA and target them
as NAIs and/or objectives to secure. Then, clear obstacles and enemy forces
before the movement of sweep elements. The sweep team moves down the
road and clears any obstacles missed or not identified during the planning
process. The main advantage of this method is that the TF commander has
immediately secured MSRs, allowing him to push out (expand forces out past
the secured area and secure additional areas) and find the enemy with a
degree of confidence that follow-on forces will be much safer.

There are two types of sweep operations— deliberate and hasty. Deliberate
and hasty clearance operations can be modified to meet the time and
equipment limitations of the TF, but the commander assumes greater risk
when the clearance type is modified.

Route and Area Clearance 11-13

C3, FM 20-32

Deliberate

A deliberate sweep (Figure 11-7) is very thorough and includes a complete
sweep of the entire road (shoulders, culverts, ditches, and bridges). It is the
most time-consuming sweep operation and relies on electronic (primary) and
visual (secondary) detection systems.

Support force

\m

Breach force

\

m m ^ ^

\

>

/

/

^

[£><^ Assault force

>

MP

c£

- — , /

/

Hasty

Figure 11-7. Deliberate route clearance

The platoon sweep team (Figure 11-2, page 11-9) is dismounted to focus its
attention on the entire length of the route. The support force (company-size)
secures at least 100 meters on the flanks and 100 meters forward to clear
possible enemy direct-fire systems and overwatching elements in front of the
breach force. This not only allows the breach force to focus solely on the route
but also clears the area of off-route and command-detonated mines.

If enemy contact is made, the support force fixes the threat whilethe assault
force reacts. The sweep teams withdraw to a location that provides
concealment and/or security. Mechanical detection provides a third means of
detection and is the method used to proof the route after the sweep team has
passed through the area. The deliberate sweep includes a route
reconnaissance and looks at all areas of a route, including bypasses. The
del i berate sweep focuses on thoroughness rather than speed. This method is
very slow and tedious and should only be used when time is not a factor; 80 to
100 meters can be covered per hour.

A hasty sweep (Figure 11-8) consists of visual inspection, physical search or
probing, and the use of mine detectors. It is the fastest, most risky method and
is suited for an armored or mechanized team. It relies primarily upon visual

11-14 Route and Area Clearance

C3, FM 20-32

detection (thermal sights or the naked eye) for minefield identification. The
breach force looks for mines, wire, and other minefield indicators. The road
surface, culverts, ditches, and bridges are inspected and searched. Visual
detection is accompanied by a mechanical proofing system. Electronic mine
detectors are used by sweep teams to check all suspected areas.

Support force

/

Breach force

" JSJ

M

)S$ m <-)

^

\

m O >

m

MP c}

/

Assault force ^

"V

Figure 11-8. Hasty route clearance

The support force includes a maneuver platoon that provides overwatching
fire and/or security. Actions upon enemy contact are the same as in a
deliberate sweep. The primary objective of this technique is speed, moving
approximately 3 to 5 kph. This method is extremely similar to the instride
breach method when encountering minefields.

The sweep team focuses on identifying immediate risks to traffic, neutralizing
those risks, and continuing on with the mission. A hasty sweep is used during
the combat clearance method to validate the areas that were not deliberately
cleared by the sweep team. It is also used if the METT-TC analysis does not
permit a deliberate sweep or if the need for a road to be opened is urgent.
Time and distance factors may be imposed. A light force may not have an
MCR system but can conduct the same sweep method with an improvised
roller system, or the force can use a sandbagged, 5-ton truck moving
backwards as a last-resort method. Using MCRs or their equivalent is
absolutely imperative due to the high risk of encountering a minefield. The
mine rake or plow is not a satisfactory substitute because it destroys road
surfaces.

AREA CLEARANCE

Area clearance is also a combined arms mission. Clearing operations occur
when engineers receive a mission to clear an area of mines or to clear a

Route and Area Clearance 11-15

C3, FM 20-32

Planning

Intelligence

specific minefield in a friendly AO. In most cases, the minefield has been
reported and may already be marked on all sides. The engineer unit receiving
the mission must base its plans on available information and prepare
equipment based on the estimate.

Planning area-clearance operations is very similar to planning breach
operations. Commanders and staffs plan and coordinate all the breaching
tenets.

I ntelligence is particularly important for discovering the types of mines and
mine fuses the enemy employs. The engineer uses this information to
determine which clearance and neutralization techniques offer the best
chance for success and minimize the risk to the sweep teams. I ntelligence also
helps the commander determine the need for outside resources, such as EOD
and SOF elements.

The information needed for area-clearance operations includes—

• Minefield location.

• Minefield orientation.

• Presence of wire as an obstacle.
Location of gaps and bypasses.

• Minefield composition (buried or surface-laid mines, AT or AP mines,
AHDs, tripwires, and minefield depth).

• Types of mines, employment techniques, fuses, and booby-trap
configurations.

Information on whether or not the minefield is marked and, if it is
marked, the material used.

• Possibility of hostile forces in the area.

Fundamentals

Organization

Mass

You must plan to apply the four fundamentals of breaching operations
(SOSR), but you may not execute all of them due to the lack of enemy
presence.

Task organization is similar to that used for route-clearance operations. The
breach force is the clearance element, and the support force is responsible for
all security and maneuver responsibilities. There is no assault force in area-
clearance operations. Table 11-3 shows a sample task organization for an area
clearance. The size of the force can be tailored, based on the probability of
contact.

Sufficient maneuver and engineer assets must be allocated to the clearance
company team. The length and width of the route and the amount of time

11-16 Route and Area Clearance

Table 11-3. Sample task organization for an area clearance

C3, FM 20-32

Team

Support Force

Breach Force

Heavy

Mechanized infantry platoon

• Mortar section

• FIST

• Armor platoon

• Engineer platoon with
organic vehicles

• Medical team (two
ambulances)

• EOD team

Light/heavy

• Bradley platoon with dismount
capability

• 60-mm mortar section
Forward observer

• One infantry platoon (light)

• Engineer platoon with
organic vehicles

• Medical team (two
ambulances)

• EOD team

Light

• AT/MP section with M60/MK19 mix

• 60-mm mortar section
Forward observer

• Two infantry platoons (light)

• Engineer squad (-)

• Medical team (two
ambulances)

• EOD team

avail able determines the size of the sweep team. A platoon is normally used to
clear a 200- by 300-meter minefield; additional assets are required to clear
larger and multiple minefields.

Synchronization

All aspects of synchronization should be implemented when planning area
clearance. It is especially important that rehearsals be conducted at the
combined arms level. Rehearsals should include—

• Reaction to enemy contact.

• Reaction to an ambush.

• Communications exercise.

• Fire support (obscuration smoke, immediate suppression fires, critical
friendly zones for counterfire radar, and no-fire area around the
clearance site).

• CSS (maneuver, casualty evacuation, marking materials, and
demolitions resupply).

Planning Considerations

Area-clearance BOS planning considerations are parallel to route-clearance
planning considerations. Brigade and battalion TF staffs should use the
planning considerations outlined on pages 11-3 through 11-7 plus the ones
outlined below:

• Intelligence. Focus on the most probable enemy attack method and
AAs.

• Maneuver.

— Clear and secure flanks (at least 500 meters) and thefarsideof the
area to be cleared.

— Provide security for the cleared area.

Route and Area Clearance 11-17

C3, FM 20-32

Fire support. Ensure that the area-clearance team has a FIST
coordinator. The FIST should be col located with the support force 01 C.

M obi I ity/survi vabi I ity. Establish minefield control points along the
area to be cleared.

CSS.

— Ensure that the medical team consists of one or two ambulances
and that it is located with the breach force.

— Ensure that all personnel wear flak vests or I BASIC (Figure 11-1,
page 11-6).

C2.

— Determine the area length, using clearly definable perimeter
poi nts.

— Coordinate with adjacent units, the host nation, NGOs, PVOs, and
SOF.

Task Organization

Support Force

Breach Force

The battalion TF will focus a company team (minus) as the main effort to
conduct area clearance.

This force is comprised of two maneuver platoons and an 01 C. The support
force provides flank security, forward security, and protection for the breach
force. It neutralizes hostile forces that are encountered by the company team.
The support force secures the area 500 meters beyond the area to be cleared.
METT-TC factors will affect the actual distance based on the threat and the
weapon systems. The support force 01 C establishes static security positions
around the area until the clearance operation is complete. He also has control
of fires and the responsibility to neutralize any hostile force.

The breach force is comprised of an engineer platoon that is organized into
sweep teams, a medical team, and an EOD team (or one that is on call). The
sweep team (squad-size) is organized as shown in Figure 11-3, page 11-10. The
breach force's mission is to sweep and clear the area of mine and explosive
threats.

Methods and Types

The breach force 01 C determines the perimeter of the area to be cleared and
ensures that it is marked. The 01 C divides the area in to sect ions to be cleared
(Figure 11-9). The sections should be no larger than 40 meters wide and 100
meters long. This is an optimal-sized area for a sweep team to clear at one
time. The 01 C assigns squad-size sweep teams to each section.

The squads clear their assigned sections using the sweeping techniques
discussed earlier in this chapter. As the sections are cleared, they are marked
for safety and control purposes. This process is continued until the entire area
is cleared. Progress is reported to the company team commander as required.

11-18 Route and Area Clearance

C3, FM 20-32

m

Support force OIC

100 mf

100 m

Sweep teams
(lanes are 2 m)

Figure 11-9. Area clearance site layout

IMPROVISED MINE THREAT

Mines are not always employed conventionally by military forces organic to
the host nation or its enemies. I n many cases, they are also employed by
terrorists against allied forces or the host-nation populace. In these cases, the
threat increases because of the improvised methods in which the mines were
emplaced. I n conventional emplacement of mines, a pattern emerges from the
emplacing force's doctrine, and the threat can easily be reduced by using this
knowledge. There is less pattern in the case of improvised mining methods,
and this makes detection and removal very difficult.

Improvised mining has many different employment techniques. In most of the
techniques shown below, a UXO can easily be employed in place of a mine:

• Coupling mines. Coupling is done by linking one mine to another,
usually with detonating cord. When the initial mine is detonated, it
detonates the linked mine. This technique is done to defeat
cou ntermi ne equi pment.

• Boosting mines. Buried mines are stacked atop one another, and the
farthest mine from the surface is fused. This reduces the probabil ity of
detection and increases the force of the blast.

• Sensitizing AT mines. On some nonmetallic AT mines, the pressure
plate can be cracked and the spring removed or the mine's explosive
can be cut into smaller blocks and employed as powerful AP mines.

Route and Area Clearance 11-19

C3, FM 20-32

The pressure plate can be removed from metallic AT mines and
employed in the same manner. Alternatively, a pressure-fused AP
mine can be placed on the top of an AT mine.

Mixing training mines with live mines. Hostile forces can employ
training mines at the start of a minefield and emplace live mines
toward the end. The sweep element falsely believes that the minefield
is phony and becomes complacent in its reduction activities. When this
technique is used, live mines are painted to resemble training mines.

Daisy-chaining mines. Command-detonated AP mines are commonly
used in daisy chaining. Hostile forces link the mines with tripwires or
detonating cord. When the initial mine is detonated, the other mines
will detonate.

MINE LOCATIONS

Hostile forces normally place more than one mine in each mined area. Do not
focus the detection effort solely on a horizontal mine threat, such as on the
ground or in culverts. The mine threat is also vertical, such as in trees or
attached to an overpass. Clearance efforts must accommodate the three-
dimensional battlefield. Mines may be placed in—

Frequently used roadways.

Brush and other traffic obstructions placed on roadways.

Bridge bypasses and fording sites.

Road junctions.

Obvious turnarounds, bypasses, culverts, ditches, and shoulders.

Key logistic points (water, fuel, food).

Debris along a route.

DISPOSITION OF MINES

The following actions should betaken when a suspected mine is found:

• Mark the suspected mine location; do not leave any mine unmarked.

• Search for electric wires and trip wires in the immediate area. Trace
the wires in both directions to determine if items are attached to
them. If there is nothing attached and the IPB does not state
otherwise, cut loose trip wires and electric wires.

DANGER
Never cut taut trip wires. Alert the security element to search for an enemy that
may be manning a command-detonated mine. Keep troops away from the mine
until all the wires are traced and cut. Be alert for booby traps and ambush. If
booby traps are found, use the clearance procedures outlined in Chapter 13.

Probe the suspected mine location and uncover enough of the object to
identify it. Other personnel should stay at least 30 meters away.

11-20 Route and Area Clearance

C3, FM 20-32

If the object is a mine, the prober withdraws and notifies the 01 C.
The OIC decides to bypass the mine, destroy it in place, remove it
with a grapnel, or notify EOD for hand neutralization.

If the object is debris, get in a protected position and carefully
remove the debris with a grapnel hook. Be alert for booby traps or
AHDs wired tothedebris.

Mine-Removal Techniques

A mine can be bypassed, detonated in place, pulled out by a rope or a wire, or
neutralized and removed by hand. The method used depends on the location of
the mine, the type of the mine and the fuse, and the tactical situation.
Methods of removal and actions on finding a mine should be addressed in the
OPORD and rehearsed prior to executing the mission.

Trip-wire and tilt-rod mines can be detonated by throwing a grapnel, with a
rope attached, past the tri p wi re or ti It rod and pul I i ng the grapnel back to
actuate the mine. Grapnels may be improvised from any available material,
such as a bent drift pin or scrap material.

A hand-emplaced charge is thestandard demolition material used to destroy a
mine in place (see FM 5-250). A 1-pound block of explosive placed next to a
mine is sufficient to detonate most mines. A charge can be placed next to each
mine in a group, then the charges can be connected and fired simultaneously.

Rope or wire can be used to pull a mine out of its installed position. This is a
safe method and only detonates mines that are equipped with AHDs. It also
reduces noise and cratering. A tripod (Figure 10-21, page 10-23) makes it
easier to pull a mine out of a hole on the first attempt. Use the following
procedures to remove mines:

• Uncover only enough of the mine to expose a handle or a projection.
Attach a 60-meter length of rope or wire to the mine or engage a
grapnel. If there is no projection, engage a grapnel on the bottom side
of the mine, opposite the direction of pull.

DANGER
Do not move the mine while uncovering it or attaching
the rope because movement might detonate an AHD.

Ensure that the covered area is not mined. Take cover and lie in a
prone position at least 50 meters from the mine. Pull the rope to
remove the mine from the hole.

Wait at least 30 seconds before leaving cover and approaching the
mine if the mine type is unknown. This guards against the possibility
of a delay firing mechanism.

Dispose of the mine according to the unit directive or SOP.

Hand Neutralization

Appendix A discusses procedures for hand neutralization of US mines.
Foreign mines and booby traps should only be neutralized by EOD personnel.

Route and Area Clearance 11-21

C3, FM 20-32

SAFETY

REPORTS

Mines are neutralized by hand, when—

U nits are conducting a covert breach.

The mine is located on a bridge, building, or other facility required for
use by friendly forces.

Neutralization by other means is not possible.

The mine can be positively neutralized by hand and is required for
reuse.

The mine type is unknown and recovery must be attempted for
intelligence purposes.

Chemical mines are located in areas where contamination would
restrict the use of the area by friendly troops.

The following safety procedures should be observed during route and area
clearance:

• Personnel should wear helmets and flak jackets to protect them
against fragmentation. Sweep team members should wear I BASIC, if
available.

Vehicle floorboards should be sandbagged.

Vehicles should be dispersed at 50-meter intervals. This ensures that
a mine detonated by one vehicle will not cause casualties in other
vehicles.

One person at a time should be allowed at a suspected mine location.

Personnel should assume that mines and explosive devices are
equipped with AHDs until proven otherwise.

Personnel should not run and should move only in previously cleared
areas.

Armored vehicles should have their hatches open to vent the pressure
pulse from a mine detonation.

Soldiers should wear ballistic and laser protective spectacles (BLPS)
or lightly tinted, protective eyewear to reduce eye fatigue and improve
their ability to recognize mine indicators.

Dissemination of information is the key to battlefield management. U nits
encountering minefields or explosive devices should follow a five-step
process— stop, secure, mark, report, and avoid. Units must provide adequate
information to their higher headquarters to ensure that follow-on elements
are well informed. I nformation must include the known or suspected
minefield location, types of mines (if known), the marking method, the time
the minefield was encountered, and any additional information that may be of
use to the clearing unit.

Division and maneuver brigades must establish a central control cell for mine
clearance information. This cell receives and gathers all mine and explosive

11-22 Route and Area Clearance

C3, FM 20-32

threat data within the unit's AO. M ine-contact reports are reported through
maneuver command channels with a priority of flash or immediate. The
information is then jointly controlled in the operations cell and the central
mine control cell by the engineer staff officer, the G3/S3, and the Assistant
Chief of Staff, G2 (Intelligence) (G2)/S2. The mine contact database is jointly
maintained by the engineer andtheG2/S2, who subsequently conduct pattern
analysis and integrate it into intelligence and operational updates.

The central mine control cell performs the following actions:

• Maintains a current situation map and overlay that depict friendly
and enemy mines and obstacles.

• Maintains and updates enemy obstacle (Figure 11-10, page 11-24) and
route status (Figure 11-11, page 11-25) information.

• Receives and maintains minefield recording forms (US and foreign)
within the unit's operational area (this includes host-nation minefield
data, if available).

• Maintains a mine-contact database. (This could be a clearinghouse for
future operations.)

• Processes, analyzes, and updates information; disseminates the
information to subordinate commanders and staff.

Situation Report

Clearing units submit a situation report to higher headquarters if enemy
activity is encountered or if an explosive device is discovered. This information
should be tracked in the TOC and the CTCP. I nformation must be
disseminated to subordinate units, especially CSS elements.

Progress Report

The clearing unit submits progress and completion reports until the clearance
operation is complete. Progress reports must be timely and accurate. Report
format and frequency are established intheOPORD before the clearance
mission is executed.

Route and Area Clearance 11-23

C3, FM 20-32

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11-24 Route and Area Clearance

C3, FM 20-32

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Route and Area Clearance 11-25

C3, FM 20-32

Mine Incident Report

A mine incident includes any unplanned activity involving a mine, UXO, or a
booby trap. It also includes near misses that could have resulted in damage or
injury. The mine incident report (Figure 11-12) is a technical report that
follows a serious incident report (SI R), and it should be submitted as soon as
possible (local SOP will indicate time requirements).

MINE INCIDENT REPORT

DATE:

FROM: THRU: TO:

REFERENCE SIR #

A. Incident DTG

A1. dd/time/zone/mm/yy

B. Incident location

B1 . Map sheet/UTM/grid reference (8 digit)

Include a site sketch as an
attachment.

B2. Location (road, field, building)

B3. Emplacement (buried, surface-laid, off-
route)

C. Effects (to
complement
information already in
the SIR)

C1. Casualties (rank, name, date of
awareness training, time in the mission area,
protection equipment used)

C2. Vehicle damage (number, type, extent of
damage)

Include a photo if possible.

C3. Collateral damage

D. Device suspected

D1 . Type of mine (AT, AP, make, model)

D2. Type of booby trap (pull, release,
pressure)

D3. Type of UXO (dropped, thrown, projected)

D4. Unknown (detail, color, shape, size)

E. Circumstances

E1 . Activity at the time of the incident

E2. Degree of previous use of the route, area,
location

E3. Date of previous clearance and proofing
by engineers

E4. Where the route, area, or location is
monitored

F. Recommendations

F1. Recommendations to prevent
reoccurrence

G. Miscellaneous

G1 . Any other pertinent data

Figure 11-12. Sample mine incident report

11-26 Route and Area Clearance

PART THREE

Special Mining Operations

Part three provides tactical and technical information on special-mining operations,
such as using booby traps and expedient devices. It also discusses mining in rivers,
urban terrain, and unique environments. Restrictions and responsibilities are outlined
in detail for the employment and the clearance of special mines and devices.

Chapter 12

Mining Operations in Special Environments

Mines areemplaced and encountered in all environments, some of which
need special consideration to understand effective employment, detection,
and/or removal .

STREAMBED AND RIVER MINING

Employment

Conventional AT mines are much more effective in water than on land
because water transmits the shock effect better than air. Vehicle support
members, tracks, and wheels are damaged by a mine blast. Small vehicles are
overturned and almost completely destroyed. Because water amplifies and
transmits shock waves, mines equipped with pressure-actuated fuses are
subject to sympathetic detonation at greater distances in water than on land.

M15 and M19 AT mines can be used for streambed and river mining. The M 21
AT mine should not be used because it is very difficult to arm and disarm
underwater, and it can be easily functioned by drifting debris. To avoid
sympathetic detonation, AT mines must be at least 14 meters apart in water
that is less than 61 centimeters deep, and at least 25 meters apart in water
that is deeper than 61 centimeters. The mined areas are chosen to take
advantage of stream and adjacent area characteristics. Water depth within
the minefield should not exceed 1 meter because it is difficult to work in
deeper water, and pressure-actuated fuses are usually ineffective against
waterborne vehicles.

Current velocity must be considered when emplacing mines in a streambed or
a river. If the mines are placed deeper than 45 centimeters, they must be
recovered by engineer divers:

• A lightweight diver has diving restrictions based on current velocity.

• A scuba diver is restricted to a maximum current velocity of 0.5 meter
per second.

Mining Operations in Special Environments 12-1

C2, FM 20-32

• A surface-supplied diver is restricted to a maximum current velocity of
1.3 meters per second.

Seasonal current velocity should also be considered if the minefield is to be in
place for an extended period of time. Additional information on diving
restrictions can be found in FMs 20-11 and 5-490.

Since sand in inland waters continuously moves downstream, it may be
difficult to locate and remove mines planted on sandbars or downstream from
sandbars. If the site has a muddy bottom, the mud should not be deeper than
46 centimeters and there must be a hard base underneath it. The enemy is
unlikely to choose a fording point where vehicles mire easily. If underwater
obstacles (gravel, rock, stumps) are bigger than the mine, the area cannot be
easily mined. If such areas must be used, place the mines so that they are
exposed to vehicle wheels or tracks. Armored vehicles usually enter and exit
streams at points where the incline is less than 45 percent. After entering a
stream, vehicles often travel upstream or downstream before exiting.
Carefully examine riverbank formations and underwater obstacles to predict
the trail a vehicle will use to ford the stream.

Emplacement

When emplacing mines in streams and rivers, always work in pairs. Prepare
the mine on land near the emplacement site. Coat fuse threads and wells with
silicone grease (a waterproof lubricant) or a heavy grease to minimize the
chances of water leaking into the mine. Waterproof joints between the
pressure plate and the mine case with silicone grease. As a rule of thumb,
waterproofed mines are reliable up to 3 months when immersed without
waterproof coveri ngs. Secure the mine with outriggers to prevent drifting:

• Construct field-improvised outriggers with—

— Two green limbs that are about 3 centimeters in diameter and 1
meter long. Green limbs are recommended because they are
stronger and less likely to float than those which aredried out and
dead. (Steel pickets, sign posts, fence rails, or similar items having
the proper dimensions may also be used.)

— Two pieces of clothesline, manila line, or similar material that are
about 1 meter long.

• Fasten the limbs to the underside of the mine and secure them with
the line (Figure 12-1).

• Approach the emplacement position from the downstream side. To
prevent dragging the outrigger or contacting objects in the stream,
carry the mine by grasping its sides, not by its carrying handle.

• Place the mine and the outrigger on the stream bottom. Stake down
outriggers after they are emplaced to prevent drifting. If staking is
impossible, place sandbags or large rocks on the outriggers for better
anchorage.

• Arm the fuse.

12-2 Mining Operations in Special Environments

FM 20-32

Figure 12-1. Outrigger techniques

Recovery

WARNING
Mines may have drifted downstream and/or been tampered with by
enemy forces. Removal by any method other than explosive breaching
(see TM 9-1375-213-12) is extremely hazardous and is not recommended.
If the situation demands recovery by hand, proceed with utmost caution.

Recording

Safety

A two-person recovery team—

• Slowly proceeds 2 meters downstream from where the mine was
emplaced and then carefully probes for the mine. If the mine was
placed deeper than 45 centimeters, it must be recovered by engineer
divers.

• Removes any foreign material from thetopof themineand disarms it.

• Carries the mine ashore and removes the fuse and the detonator.

Engineer divers normally emplace new mines or mines that have not been
submersed in water; but if the mine and the fuse show no evidence of damage
or deterioration, the mine can be resused. If the mine is reused, mark it to
indicatethat it has been immersed in water; for example, place the letter l/l/on
the pressure plate.

The minefield is recorded on DA Form 1355 (Figures 12-2a and 12-2b, pages
12-4 and 12-5).

In addition to normal safety measures, underwater mining requires
evaluation of the tactical situation and application of special safety
techniques. The turbidity, the velocity, and the depth of the water and the
condition of the bottom require that laying-party personnel be able to swim
well. Prolonged immersion of personnel, especially in cold temperatures, must
be avoided. Sudden drop-offs, rocks, and other objects that are likely to cause
personnel to lose their footing must be considered. Other safety measures
i ncl ude the fol lowi ng:

• Work in pairs.

Mining Operations in Special Environments 12-3

FM 20-32

<^Arf\Qui s*e**J (when completed)

313TOS80 SI 19 W M NOUI03

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Figure 12-2a. Sample DA Form 1355 (front side) for river mining

12-4 Mining Operations in Special Environments

FM 20-32

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Mining Operations in Special Environments 12-5

FM 20-32

Emplace mines from upstream to downstream to prevent personnel
and equipment from being swept into the mined area.

Stay on the downstream side of the mine when arming the fuse.

Place the mine as flat as possible on the bottom to prevent drifting.
Use green saplings or other nonbuoyant material to construct
outriggers.

Do not arm the mine before it is laid.

Carry the mi ne horizontal ly or edgewise to the current to reduce water
resistance on the mine's pressure plate.

URBAN-TERRAIN MINING

Characteristics of urban areas (such as a high proportion of hard-surfaced
roads) prohibit a simple transition from open- to urban-area mine
employment techniques and doctrine. The advantages of abundant cover and
concealment, maneuver restrictions, and observation already possessed by the
defender of an urban area can be significantly enhanced by the proper use of
mines. Terrain modified through the process of urbanization provides a
unique battle environment.

The major characteristics of urban terrain which are likely to impact on mine
warfare i ncl ude the fol lowi ng:

• Multistoried buildings add a vertical dimension to the battle.
Basements and floors become part of the battle scene. The
vulnerability of combat vehicles increases because attack from above
or below is likely.

• F ighting is done at close range, often face-to-face, and seldom exceeds
50 meters. Some weapons, particularly large-caliber weapons, are
unsuitable at a short range.

• Sewers, subways, and tunnels provide covered and concealed
passageways for the movement of troops on both sides. Detailed
knowledge of the location and the status of these tunnels is needed to
successfully wage an urban battle.

• Streets and parking lots are modified to withstand continuous use by
vehicles. Major routes and lots are paved. A high density and complex
pattern of streets provide numerous avenues of advance. Burying
mines is extremely difficult. Most mines are surface-laid and
camouflaged with rubble and debris to avoid detection.

• Movement by vehicle is difficult. Streets are littered by rubble and
cratered if the city has been bombed or subjected to artillery attack.
Bridges and overpasses are likely to be destroyed or blocked. Traffic
flow is highly channelized.

• Extensive map and chart data are needed by the commander. For
example, the commander should know the locations of telephone,
electric, gas, water, and sewer connections; substations; and
generating and pumping stations.

12-6 Mining Operations in Special Environments

FM 20-32

Antipersonnel Mines

US policy prohibits the use of non-self-destructing AP mines for all US forces
except those on the Korean Peninsula. However, US forces can expect to
encounter AP mines that are emplaced by other countries in support of
MOBA. They are employed to block infantry approaches through or over
underground passageways; open spaces; street, roof, and building obstacles;
and dead spaces.

When AP mines are encountered (Korea Only: or used) in MOBA, mine
locations are recorded on DA Form 1355 as shown in Figure 12-3)

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Underground Passageways

Open Spaces

Subways, sewers, cellars, and utility tunnels provide protected movement
routes for troops. I n large cities where underground systems are numerous
and complex, limited manpower may dictate that forces employ obstacles to
block key passageways with wire and AP mines. (See Figure 12-4, page 12-8.)

Open spaces include gaps between buildings, courtyards, residential yards,
gardens, parks, and parking lots. In some cases, mines can be concealed in
rubble or buried. However, the characteristics of most terrain surfaces,
coupled with limited time and resources, dictate that mines be surface-laid.
(See F igure 12-5, page 12-8.)

Mining Operations in Special Environments 12-7

FM 20-32

Trip wire

Wire/rubble

Enemy

Unattended sensors

Warning sign
for defenders

/

Figure 12-4. Underground passageway

Concealed AP mines
with trip wires

AP

minefield

¥ * *

¥* * *

m0m

Overw atching' fires Overwatching fires

AP

minefield

Figure 12-5. Open spaces

12-8 Mining Operations in Special Environments

FM 20-32

Street Obstacles

Hand-emplaced AP mines can be emplaced on street surfaces, on railroad
lines, and in areas along shallow waterways. (See Figure 12-6.)

Roof Obstacles

Figure 12-6. Street obstacles

M ines and booby traps supplement wire obstacles to deny operations that
require air assault onto rooftops. They also prevent occupation on roofs that
afford good observation points and fields of fire. (See Figure 12-7.)

Overwatching fires

Wire with booby traps
and directional
^mentation mines

Antihelicopter
obstacle

Figure 12-7. Roof obstacles

Mining Operations in Special Environments 12-9

C2, FM 20-32

Building Obstacles

Building obstacles include areas within and adjacent to buildings. Forces can
lay mines in conjunction with wire obstacles to deny infantry access to covered
routes and weapon positions (Figure 12-8).

Boarded up window

Directional AP mine

Buried directional
' AP mine wire

With trip
wires

¥

With trip
wires

With trip
wires

With trip
wires

-Vm^'

Overwatching fires

Overwatching fires
Defensive fires

Overwatching fires <§■

Dead Spaces

E mployment

Figure 12-8. Building obstacles

Obstacles and mines can be emplaced to restrict infantry movement in areas
that cannot be observed and in areas that are protected from direct fire.

The following AP mines are effective in urban terrain:

• M14 (used by US forces in Korea only). Its small size makes it
ideal for obscure places, such as stairs and cellars. It can be
used in conjunction with metallic AP and AT mines to confuse
and hinder breaching attempts. (See Figure 12-9.)

• M16 (used by US forces in Korea only). With trip-wire
actuation, its lethal radius covers large areas such as rooftops,
backyards, and cellars. An added advantage can be gained by
attaching twine or wire to the release-pin ring to expediently
rig the mine for command detonation. (See Figure 12-10.)

• M18A1 (claymore). Numerous innovative applications of claymore
munition deployment can be found for defensive warfare in urban
areas (Figure 12-11, page 12-12). With remote firing, a series of
claymore mines along a street establishes a highly effective ambush
zone. M ines can also be employed on the sides of buildings, in
abandoned vehicles, or in any other sturdy structure. Numerous
opportunities exist for effectively sited, well-concealed mine
employment above the terrain surface. Claymore munitions can be
used to fill the dead space in the FPF of automatic weapons. They
present a hazard when used in confined, built-up areas. Exercise
caution when using them close to friendly forces because there is a
danger of backblast.

12-10 Mining Operations in Special Environments

C2, FM 20-32

In footpaths

Under thresholds

At base of walls and fences

Figure 12-9. Probable M14 AP mine emplacement

Rooftops

Trip wire (command-
detonated)

Figure 12-10. Probable M16 AP mine emplacement

Mining Operations in Special Environments 12-11

C2, FM 20-32

On streets

Outside
buildings

In rubble

In alleys

I On streets

/ ■
ing fires

V*

Coverage for dead spaces

<£_ v/^c<-A^Si\*>.L

Figure 12-11. Probable M18A1 munition emplacement

Conventional Antitank Mines

Enemy tanks, infantry fighting vehicles (I FVs), and direct-fire support
weapons are restricted to streets, railroad lines, and, in some instances,
waterways. (See Figure 12-12.) M15, M19, and M21 mines areused primarily
in tactical and nuisance minefields; but they are occasionally used in
protective minefields. They should be employed with other obstacles and
covered by fire. Conventional AT mines emplaced in streets or alleys block
routes of advance in narrow defiles. Concealment of large AT mines is
accomplished by placing them in and around rubble and other obstacles.
Extensive labor requirements generally prohibit burying mines in difficult
terrain types.

In dispersed residential areas, obstacles are required to reduce the enemy's
infantry mobility through and between houses and in open areas. They also
prevent armored vehicles from moving between houses and along streets. AT
minefield patterns should extend outward from the streets, incorporating
open areas between buildings and streets to prevent easy bypass of street
obstacles.

Significant labor and mine materials are required to deploy conventional
mines between widely spaced buildings, in high-rise construction, and in
industrial and transportation areas. Therefore, SCATMINEs should be
seriously considered as viable alternatives. Some situations, such as the one
shown in Figure 12-13, provide opportunities for the effective employment of
mines in tactical and nuisance minefields.

12-12 Mining Operations in Special Environments

FM 20-32

Off-route AT
mine

I

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cz

Figure 12-12. AT mine emplacement in urban areas

BHi.A

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Figure 12-13. AT mine emplacement in industrial and transportation areas

SCATTERABLE MINES

Area-Denial Artillery Munitions and Remote Antiarmor Mines

I n addition to the advantages (such as reducing required resources and
emplacement time) applicable to all SCATM I NE systems, ADAMs and
RAAMs have two specific advantages. They are the most rapidly deployed
SCATMINE systems, and preplanning artillery-delivered minefields increases
the rate at which nuisance minefields can beemplaced. Secondly, these mines
can be delivered under enemy fire. Employment of ADAMs and RAAMs is
most effective when the enemy's intentions are known and their forces are
committed to an avenue of advance. (See Figure 12-14, page 12-14.)

Mining Operations in Special Environments 12-13

FM 20-32

Artillery delivery

NOTE: Unshaded areas cannot
be mined by assigned artillery.

Potential enemy route
through areas with _.
low mine-density

Figure 12-14. ADAM/RAAM employment

Using ADAMs/RAAMs in urban terrain involves five specific problem areas:

• Difficulty in precise minefield siting. Accurate siting is extremely
critical due to the typically restrictive avenues of advance and maybe
futile due to the difficulty in adjusting artillery rounds in an
environment that obscures observation. Further, buildings tend to
create unmined shadow zones.

• Uncertainty of ADAM/RAAM survivability upon impact with a
building or ground surfaces that are characteristic in urban areas.

• Likely availability of artillery firing units. ADAM/RAAM
emplacement may not be a priority of the maneuver commander,
because his supporting units may not have enough ADAM/RAAM
munitions on hand. Assuming the availability of artillery assets for an
ADAM/RAAM mission could prove disastrous for defending forces.

• High detectabi I ity of these mines on bare and lightly covered surfaces.
This permits the enemy to seek out unmined passageways or pick
through lightly seeded areas. If you use the doctrinal guidelines for
emplacing artillery-delivered mines on top of the advancing enemy or
immediately in front of them, the desired obstacle intent (disrupt,
turn, fix, block) and enhanced fires are achieved.

• Difficulty in achieving a good, random pattern. Hard-surfaced areas
cause mines to bounce and roll. Some mines (especially AT mines) will
land on top of buildings and are ineffective.

12-14 Mining Operations in Special Environments

C2, FM 20-32

Air Volcano

The primary advantage of the air Volcano system is its capability to site and
emplace minefields accurately. This depends on the helicopter's
maneuverability over the selected minefield terrain and the proper
coordination between ground forces and aviation support. Disadvantages
include vulnerability and the high replacement cost of the helicopter.
However, in view of the system's operational concept, employment in urban
terrain (which provides little exposure of the helicopter) actually increases the
practicality of employing this system in urban areas. Mine survival rate on
impact with a hard surface is another potential problem.

Ground Volcano

Three aspects of the ground Volcano distinguish it from other SCATMI NE
systems:

• The dispenser is organic to supporting combat engineers, making it
readily available to support the maneuver commander's defensive
plan.

• Delivery siting is accurately pinpointed tothe ground.

• Better opportunities exist to record the presence of a minefield. In
contrast to artillery-delivered and air Volcano systems, the ground
Volcano is delivered by engineers who are normally located with and
report directly to the maneuver commander.

Some primary factors may degrade ground Volcano deployment in urban
terrain. The requirement to emplace minefields before an actual attack in
order to reduce system vulnerability is the most significant factor. This makes
the minefield detectable and provides more reaction time for the enemy to
alter their scheme of maneuver. The delivery of mines depends on terrain
trafficability. The prime mover and the launch vehicle must negotiate the
terrain over which mines are to be dispensed.

Modular Pack Mine System

Gator

The MOPMS is ideally suited for employment in urban terrain (Figure 12-15,
page 12-16). The module can be hidden from enemy view, and the mines can
be dispensed after attackers are committed to a route of advance. Additionally,
mines can be emplaced rapidly under enemy fire. I n contrast to other
SCATMINE systems, the commander controls when and where mines are
dispensed and how they are detonated, regardless of the enemy situation.

When considered for employment in urban terrain, Gators encompass the
same problems as artillery-delivered and air Volcano mine systems.

Deception Measures

Phony minefields can be established rapidly with negligible effort and cost.
They have the distinct advantage of blocking the enemy but not friendly
forces. Although it is difficult to fake a surface-laid minefield, expedients such
as soup pans, seat cushions, and cardboard boxes have historically proven
effective in delaying and channelizing attacking forces. These objects, as well

Mining Operations in Special Environments 12-15

FM 20-32

MOPMS transmitter

o\ a » a

MOPMS

Direction of enemy advance

Figure 12-15. MOPMS employment

as other ones readily available in urban areas, can be used as phony
minefields or used to cover real mines. A more realistic phony minefield could
be created with i nert or training mi nes.

I nadequate minefield camouflage in urban terrain is viewed as a critical
constraint in deploying conventional mines and SCATMINEs. Smoke can be
deployed from various dispensers, but it must be dense and accurately
employed and released.

SPECIAL ENVIRONMENTS

Cold Regions

Mine employment in cold regions poses special problems— the principal one
being emplacement. Mine burial is extremely difficult in frozen ground. The
freezing water in soil causes it to have high strength and penetration
resistance, so digging times are greatly increased if not impractical. However,
there are several means to overcome this problem. I n some cases, the
minefield can belaid out before the soil freezes. To do this, dig holes for each
individual mine and insert a plug into the hole to protect its shape and
prevent it from being filled in. A wide variety of material can be used for
plugs. Ideally, the plug should be economical, easy to remove, and rigid enough
to maintain the depth and shape of the hole. Sandbags, plastic bags filled with
sand or sawdust, or logs make excellent plugs. If the minefield cannot be
prechambered, mechanical means can be used to dig holes. When available,
civilian construction equipment (particularly large earth augers) can be used
to drill holes for mine emplacement.

12-16 Mining Operations in Special Environments

J UNGLES

Deserts

FM 20-32

To assure detonation of buried, pressure-actuated mines, they should be
placed in a hole that is shallow enough for the pressure plate to be above
ground. Covering spoil should be a maximum of 1 centimeter deep.

When burial is impossible, mines are placed on the surface. Heavy snow cover
may reduce the effectiveness of both buried and surface-laid mines by causing
them to be bridged. M ines laid in deep snow should be placed as close as
possible to the surface and supported by boards or compacted snow.
Waterproof mines before emplacement in cold regions. Mines can also be
placed in plastic bags before burial. I n some cases, a layer of ice may form over
the top of the pressure plate. Although the load required to break the ice is
slightly higher than that required to activate the fuse, thin layers of external
ice will have little effect on mine functioning. When possible, tilt-rod mines
should be used in cold regions because they are less susceptible to ice and
snow. Magnetic mines are not significantly affected by snow, although cold
weather decreases battery life.

Camouflaging a minefield in a cold region is difficult. Mines should be painted
white when snow is expected to remain on the ground for extended periods of
time. Minefield signature tracks should be swept away, or deliberate tracks
should be made to give the impression of a safe area.

Korea Only: When trip-wire mines are employed in snow, the wire
should be about 10 meters long, with a slight amount of slack left in
the wire. The trip wires should be supported approximately 46
centimeters above the ground to avoid degradation by snowfall.

Fuses and explosive components deteriorate very rapidly in jungle climates.
As a result, mines and mine material require more frequent and extensive
maintenance and inspection. Waterproof mines employed in humid climates.
The rapid growth of vegetation hinders maintenance recovery and removal.
Dense vegetation may cause mines to become inoperable or windblown foliage
can detonate them. F M 90-5 provides detailed information on jungle
operations.

I n desert climates, fuses and explosive components deteriorate slowly. The
terrain and the situation determine how mines will beemplaced. Mine boards
will normally be required to provide support in soft, shifting sand. M ines
emplaced in the desert have a tendency to shift position, and the spacing
between mines and rows should be increased to prevent sympathetic
detonation. Blowing sand may expose buried mines or cover surface-laid
mines. Sand may also cause mines to malfunction. It is important to realize
the difficulty of accurately recording minefield locations in vast, open, desert
areas void of recognizable terrain features. More mines are required for desert
operations. Typically, desert minefields are much larger and have a lower
density than those used in Europe or Korea. FM 90-3 provides detailed
information on desert operations.

Mining Operations in Special Environments 12-17

FM 20-32

12-18 Mining Operations in Special Environments

C2

Chapter 13

Booby Traps and Expedient Devices

During war and OOTW, booby traps can be found anywhere at anytime.
They can kill or incapacitate their unsuspecting victims. This chapter
provides information on booby-trap employment concepts, detection
techniques, marking and recording procedures, and removal guidelines.

This chapter also provides an overview of expedient devices and their
employment considerations.

Section I . Setting Booby Traps

US policy restricts the use of booby traps by US personnel. This does not
precludetheir use by other countries, so US forces may encounter them during
operations.

The use of booby traps is limited only by the imagination of the force
employing them. They—

Are usually explosive in nature.

Are actuated when an unsuspecting person disturbs an apparently
harmless object or performs a presumably safe act.

Are designed to kill or incapacitate.

Cause unexpected, random casualties and damage.

Create an attitude of uncertainty and suspicion in the enemy's mind,
thereby, lowering his morale and inducing a degree of caution that
restricts or slows his movement.

Many booby traps are constructed using military equipment and ammunition.
I mprovised traps areused during counterinsurgency missions in low-intensity
conflicts.

The corps commander is the employment authority for booby traps. He can
delegate this authority to the division commander. If authority is given to set
booby traps, US personnel will adhere to the rules for international law
applicable to armed conflict. There are several uses of booby traps that are
prohibited. Remember, these restrictions are not observed by all countries; US
personnel must still be cautious when approaching objects in areas where
booby traps are supposedly prohibited.

International law prohibits the use of booby traps as follows:

• Booby traps and other devices are prohi bited if they are attached to or
associated with—

Booby Traps and Expedient Devices 13-1

FM 20-32

TACTICS

— Internationally recognized protective emblems, signs, or signals.

— Sick, wounded, or dead personnel.

— Burial or cremation sites or graves.

— Medical facilities, equipment, or supplies.

— Children's toys or other portable objects or products that are
designed for their feeding, health, hygiene, clothing, or education.

— Food or drink.

— Kitchen utensils or appliances except in military establishments,
military locations, or supply depots.

— Objects that are clearly religious in nature.

— H istoric monuments, works of art, or places of worship.

— Animals or their carcasses.

Booby traps are prohibited in cities, villages, and other areas that
contain civilians if combat between ground forces is not taking place
or does not appear to be imminent, unless—

— Booby traps are placed on or in the close vicinity of a military
objective.

— Measures (guards, warning, or fences) are taken to protect
civilians from booby-trap effects.

Booby traps are psychological weapons. They make the enemy cautious and
slow it down. These actions, in turn, cause enemy casualties. Do not waste
time attempting to set elaborate traps that are undetectable or impossible to
disarm. Also, do not waste time developing difficult sites, because simple traps
usually have the same chance of catching the enemy. Even if booby traps are
detected and cleared, their aim is achieved.

The principles governing the use of booby traps and nuisance mines are
identical, so consider using them in conjunction with one another. They have
characteristics that make them suitable for use in different situations:

• Nuisance mines are quicker to lay and safer to use than booby traps,
and they are normally used in outside locations where they can be
buried.

• Booby traps are normally used in urban areas, structures, and places
where mines a re easily detected.

Booby traps and nuisance mines are particularly suited for defensive
operations. They are used to—

• Slow the enemy's advance.

• Deny the enemy use of facilities and material.

• Warn of enemy approach.

13-2 Booby Traps and Expedient Devices

FM 20-32

• Deter the enemy from using ground not covered by direct fire.

• Plan defensive operations.

I n offensive operations, booby traps and nuisance mines are employed on an
opportunity basis during raids and patrols. Formal instruction is not usually
issued by the staff.

Exercise caution when using bobby traps in offensive operations because they
may hinder the operation. I n advance and pursuit operations, they are
primarily used by patrols and raiding parties. They slow down enemy follow-
up actions and hinder theenemy's repair and maintenance teams after raids.

The following considerations pertain to defensive operations but may be
relevant to offensive operations and must be considered when briefing troops:

• Booby trapping is rarely given a high priority and is usually
peripheral to other engineer tasks.

• Nuisance mines are more cost-effective than booby traps, unless booby
traps are used in situations that allow their full potential to be
exploited. If it is easier, use nuisance mines instead of booby traps.

To maximize the effect of booby traps and nuisance mines, the staff provides
engineer commanders with the following information:

• Purpose. Booby traps are time-consuming and dangerous to set. Do
not waste time and effort setting traps that are unlikely to be actuated
or that are not specifically designed to achieve the required aim. For
example, if booby traps are being used against troops, small, simple
traps designed to incapacitate will achieve this result just as well as
complicated ones with large charges. If the aim is to destroy vehicles,
use mines.

• Location. The precise location for booby traps and nuisance mines can
only be determined by the setting unit. Areas must be delineated and
recorded so that there is no threat to friendly forces in the event of
reoccupation.

• Time setting starts and time available for setting. The time setting
starts affects other engineer tasks, and the length of time avail able for
setting governs the number of men required.

• Number of safe routes required. Safe routes are important during
general withdrawals where authority has been given to booby-trap
positions as they are evacuated. They also provide safe areas for the
covering force to launch counterattacks.

• Likelihood of reoccupation. Even if the enemy has not detonated booby
traps, they might have interfered with them. Therefore, do not set
booby traps when areas are to be vacated to meet short-term tactical
requirements or when reoccupation is expected soon.

I ntelligence personnel provide information to assist the setting unit in
maximizing the effect of booby traps. The nature and the type of traps
required depend on the enemy unit. For example, while paying particular
attention to dead space and defilade positions, use mines or widely dispersed

Booby Traps and Expedient Devices 13-3

C2, FM 20-32

traps (with large charges) against a mechanized enemy. Conversely, use small
traps and AP mines (in places that afford cover) against an infantry enemy.

SITING

If the first obstacle or installation the enemy strikes is booby-trapped or
nuisance-mined, he is delayed while he clears it. The enemy is further delayed
by an increased degree of caution. His troops know that additional traps and
mines can be encountered. Booby traps and nuisance mines are generally
located—

I n and around buildings, installations, and field defenses.

I n and around road craters or any obstacle that must be cleared.

I n natural, covered resting places along routes.

In likely assembly areas.

In the vicinity of stocks of fuel, supplies, or materials.

At focal points and bottlenecks in the road or rail systems
(particularly the ones that cannot be bypassed).

The setting-party commander is responsible for the detailed siting and design
of booby traps. Consider all the information about the enemy soldier and his
operating procedures when selecting places and objects to trap. Also, consider
the traps from the enemy's point of view and assess the courses open to the
enemy when he encounters them. This can expose weaknesses in your initial
plan and bring about changes to the proposed layout, or it can result in a
different location being selected. In addition, determine the effort required by
the enemy to bypass the traps. This shows whether the i mposed delay justifies
the effort required to set the booby traps in the selected location.

TYPES OF TRAPS

Booby traps are designed to—

• Be actuated by persons carrying out their normal duties.

• Take advantage of human nature.

The following booby traps can often be detected because they are designed to
make the person do something:

• Bait. Usually consists of objects that arouse someone's interest, such
as attractive or interesting items that have apparently been left
behind or discarded during a rapid evacuation.

• Decoy. The most common decoy consists of two traps— one designed to
be detected, the other designed to actuate when personnel deal with
the first one. The first trap can be a dummy. A classic form of a decoy
is to place booby traps or nuisance mines in locations from which the
decoy mine can be removed.

• Bluff. A bluff is a hoax and usually consists of a dummy trap.

13-4 Booby Traps and Expedient Devices

C2, FM 20-32

Double bluff. A double bluff only appears to be a bluff. Personnel
believe the trap is safe or can be disarmed. For example, a number of
traps can be set that are disarmed when the detonating cord is
removed from the charge. The double bluff is achieved by setting
another trap that appears to be the same, but it actually explodes
when the detonating cord is removed from the charge. Double bluffs
rely on a reduced awareness and alertness caused by repetition.

COMPONENTS AND PRINCIPLES

There are two initiation methods for explosive booby traps— electric and
nonelectric. Both methods can be constructed using many different types of
FDs. FDs can be secured to the charge (direct connection) or located away
from it (remote connection). They are actuated by one or more methods. It is
impossible to describe every type of trap that may be encountered; however,
most are constructed and operated by using components similar to those listed
below:

FD.

Power source (battery, for example).

Connection (usually detonating cord or electric wires).

Blasting cap.

Main charge.

Figure 13-1, page 13-6, shows how typical electric and nonelectric traps can be
made.

ACTUATION METHODS

Many sophisticated booby-trap devices are now being manufactured that
operate on vibration, sound, temperature change, and other methods. Current
intelligence on the booby trap being used in theAO should be gathered so that
countermeasures can be developed and practiced. Most FDs found in the
combat zone are simple mechanisms designed to be actuated by pull, pressure,
pressure release, or tension release (Figure 13-2, page 13-7).

METHODS OF CONNECTION

Remote

Procedures can be varied when it is safe to do so. For example, instead of
connecting the FD to a charge already in position, preconnect trap components
and then position the trap.

Small charges (up to 1 kilogram) are sufficient for AP traps, but larger
quantities can be used to increase their effect. Shrapnel can be produced by
packing stones, scrap metal, nails, or other material around the charge. AT
traps require large charges (up to 6.75 kilograms for wheeled vehicles and
11.25 kilograms or more for tracked vehicles).

Follow the procedures listed below when assembling a remotely connected
trap using an M142 FD (similar to the illustration in Figure 13-3, page 13-7):

• Design the trap and collect necessary materials.

Booby Traps and Expedient Devices 13-5

FM 20-32

Detonating cord

saj

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Charge

DIRECT

Electrical cable

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Battery

DIRECT

Charge

REMOTE

Detonating cord

DIRECT

Figure 13-1. Typical electric and nonelectric booby traps

Test the M 142 FD.

Lay the detonating cord from the charge location totheFD location.

Position the charge.

Connect the detonating cord to the charge.

Prepare the coupler.

Tape a length (46 centimeters, minimum) of detonating cord to the
coupler's blasting end.

Prepare and position the M142, set it to operate in the desired
manner, and remove the round- or square-headed pin.

13-6 Booby Traps and Expedient Devices

FM 20-32

Pressure release

Tension release

Figure 13-2. Methods of actuation

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Figure 13-3. Remotely connected traps

Ensure that the two detonating cords are not touching but can be
conveniently connected when necessary.

Remove any materials and other signs of laying, and fully camouflage
the area.

Booby Traps and Expedient Devices 13-7

FM 20-32

Direct

Arm the FD by removing the positive safety pin.
Arm thetrap by connecting the two detonating cords.

Follow the procedures listed below when assembling a nonelectric, directly
connected trap using an M142 FD (similar to the illustration in Figure 13-1,
page 13-6):

Design thetrap and collect necessary materials.

Test the M 142 FD.

Prepare and position the charge for coupling to the FD, and prepare
the explosive to receive a blasting cap.

Prepare the coupler and insert it into the charge.

PreparetheM142, set it to operate in the desired manner, and remove
the round- or square-headed pin.

Remove any materials and other signs of laying, and fully camouflage
the area.

Arm thetrap by removing the positive safety pin.

DANGER
Do not attempt to further camouflage the
area after the trap is armed.

PLANNING, SETTING, AND RECORDING

Timeliness

The setting-party commander must be given all the information and sufficient
time to carry out a reconnaissance. This allows his plan and the soldier's
briefing to be as complete as possible.

Orders and Briefing

Once the commander has finished the reconnaissance, he makes a detailed
plan, prepares the order, and briefs soldiers. Thefollowing points are covered:

• Enemy intelligence.

• Number and types of traps to be set.

• Location and design of traps (precise or general ).

• Tasking and allocation of areas.

• Recording, marking, and arming procedures.

• Control measures.

• Time requirements.

• Material and equipment availability.

• Rehearsal and equipment preparation.

13-8 Booby Traps and Expedient Devices

Rehearsal

FM 20-32

Whenever possible, rehearse laying procedures. Thoroughly exercise control
and safety measures so that any flaws in the system will be discovered. Lay
practice traps and carry out arming and recording procedures. If you cannot
rehearse at the trap location, hold the rehearsal in a similar area.

Organization and Procedure

Setting booby traps is a dangerous task and it must be carefully controlled.
Exact drills cannot be prescribed, but the following procedures should be
followed as closely as possible:

• Control point. The commander must establish a control point upon
arrival at the trap area. The control point forms a headquarters and a
material holding area. Also, safe routes start at the control point. If
the rehearsal is conducted at another area, assemble all the troops at
the control point before setting starts. At this time, relate the ground
to the plan, confirm control measures, and check FDs and equipment
for serviceability and adequacy.

• Control of parties. Each setting party consists of one or two men.
Clearly define thearea whereeach setting party will work (use tape, if
necessary). Position traps so that accidental detonation will not cause
friendly casualties. Strictly control the entry to areas where traps are
being set. I n most situations, only the commander, setting parties, and
a recorder enter areas. Troops who are not assigned tasks should
remain at the control point unless otherwise authorized by the
commander.

• Marking. As with nuisance minefields, mark booby-trapped areas
until they are evacuated. When possible, use standard booby-trap
signs (Figure 13-4). When signs are not available, use temporary
markings (any barrier or fence) to clearly indicate a booby-trapped
area. Remove the temporary marking after thearea is evacuated and
before the enemy reconnoiters the area.

Figure 13-4. Standard booby-trap sign

Setting. Setting parties transport required explosives and material to
the site. They do not arm FDs or traps until ordered to do so. If the
setting party consists of one man, he remains with the trap until it is
armed or until the commander directs him to leave. I n a two-man

Booby Traps and Expedient Devices 13-9

FM 20-32

party, one man returns to the control point and reports the completion
of the task, and the other man remains with the trap. A setting party
enters and leaves its area by the same route. If the route is not clearly
apparent, personnel lay tapes to guide the commander and the
recorder to the area.

Inspection and arming. The setting-party commander inspects traps
for safety and camouflage before giving the order to arm them. He
devises an arming plan that enables the setting parties to withdraw to
the control point in a safe and logical manner. For example, in open
areas, start arming at the furthest mine from the control point; in
buildings, arm from thetop down.

Reporting and Recording

Booby traps do not distinguish between friend and foe. Correct reporting and
recording procedures must be observed to avoid friendly casualties. The
procedures for recording booby traps are the same as for nuisance mines (see
Chapter 8). When traps are set in areas occupied by the enemy, they are not
recorded. I n this case, it is sufficient to note their location and type in after-
action reports.

Tactical Reports

I nformation about booby-trapped areas must be provided in stages from the
time they are established until they are cleared. This procedure allows up-to-
date information to be annotated on operational maps at all concerned units
and headquarters (see Table 13-1).

Booby-Trap Records

The setting-party commander compiles records for all booby-trapped areas on
DA Form 1355 (Figures 13-5a and 13-5b, pages 13-12 and 13-13). Strictly
observe the instructions printed on the back of the form. Booby-trap records
provide detailed information about the composition of an area, and they allow the
area to be cleared quickly, with minimum casualty risk. They contain complete
information on the number and types of traps set, as well as accurate and
precise details on the location and design of individual traps. If a single record
is not large enough to record all the traps set in a definable area, clearly note
this fact and reference serial numbers of adjacent records. Submit the
completed DA Form 1355, in triplicate, to the next higher headquarters.

13-10 Booby Traps and Expedient Devices

FM 20-32

Table 13-1. Tactical reports

Report

By Whom and
When Initiated

To Whom
Forwarded

Details to be Included

Intention to
set (required)

Division

commander, on
deciding to set
booby traps

• Corps HQ

• Controlling HQ

Purpose

General area to be booby-
trapped (by grid coordinates)
Estimated number and types
of traps

Estimated starting date and
time

Estimated completion date
and time

Siting
(optional)

• Setting unit, on
completion of
reconnaissance
Division
ordering
setting, only if
materially
different from
intention-to-set
report

Division

ordering setting
• Next higher HQ

Boundaries of booby-trapped
area (by grid coordinates)
Number and approximate
positions of safe routes, if any
Estimated number and types
of traps

Start of
setting
(required)

• Setting unit,
when setting
starts
Division
ordering setting

Division HQ
ordering setting
Next higher HQ

• Time setting started

• Estimated time of completion

• Number and types of traps
being set

• Any change to the detail given
in the siting report, and
whether or not it was a result
of orders

Completion
(required)

• Setting unit,
when setting is
completed
Division HQ
ordering setting

Division HQ
ordering setting
Next higher HQ

• A trace on the largest scale
map available, showing the
boundaries of the trapped
area

• Full details of the area and
buildings trapped (with sketch
maps)

• Full details of traps set,
including design and location

• Full details of all safe routes

• Total number and types of
traps

• Time and date of completion

Changes
(required)

Division HQ
ordering change

Next higher HQ
• Any other unit
holding
information on
existing traps

Full details of change

Booby Traps and Expedient Devices 13-11

FM 20-32

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Figure 13-5a. Sample DA Form 1355 (front side) for a booby-trapped area

13-12 Booby Traps and Expedient Devices

FM 20-32

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Booby Traps and Expedient Devices 13-13

FM 20-32

Section II. Clearing Booby Traps

SITES

SAFETY

Soldiers must be aware of the threat that is presented by booby traps. They
must also receive sufficient training to recognize locations and items that lend
themselves to booby-trapping. Avoid overemphasis and strike a balance
between what is possible and what is probable. For example, in medium-level
operations, overemphasis of the booby-trap threat can be counterproductive
by slowing momentum. This causes casualties that might otherwise have been
avoided. I n low-intensity conflicts where the use of booby traps and
improvised explosive devices are probably widespread, training must be given
high priority and emphasized at all levels.

Although many booby-trapped sites are similar, the items selected, the reason
for their use, and the scale of the threat are quite different. I n medium-level
conflicts, booby traps are mainly used in recently contested areas. The items
selected and the reasons for using traps are the same as those taught to our
troops. Therefore, by anticipating the presence of traps, it is possibleto isolate
and bypass trapped areas. If this is not practicable, you can plan
countermeasures, such as avoiding convenient and covered resting places
along routes where mines can be located. At bridge or ferry sites that cannot
be avoided, you must ensure that they are free of traps.

I n low-intensity conflicts where booby traps are used to cause casualties,
delays, or disruptions, no items or areas can be considered safe. Quality
collective training in booby-trap awareness is necessary for all units. Rapidly
disseminate booby-trap incident reports to all levels. This allows personnel to
develop an understanding of the enemy's method of operation and a feel for
what might or might not be targets.

The following rules and safety procedures can save your life and the lives of
others— learn and remember them:

• Suspect any object that appears to be out of place or artificial in its
surroundings. Remember, what you see may well be what the enemy
wants you to see. If you did not put it there, do not pick it up.

• Examine mines and booby traps from all angles, and check for
alternative means of firing before approaching them.

• E nsure that only one man works on a booby trap.
Do not use force. Stop if force becomes necessary.

• Do not touch a trip wire until both ends have been investigated and all
devices are disarmed or neutralized.

• Trace trip wires and check for additional traps located along and
beneath them.

• Treat all parts of a trap with suspicion, because each part may be set
to actuate the trap.

13-14 Booby Traps and Expedient Devices

C2, FM 20-32

Wait at least 30 seconds after pulling a booby trap or a mine. There
might be a delay fuse.

Mark all traps until they are cleared.

Expect constant change in enemy techniques.

Never attempt to clear booby traps by hand if pulling them or
destroying them in place is possible and acceptable.

INDICATIONS

DETECTION

Successful detection depends on two things— being aware of what might be
trapped and why, and being ableto recognize the evidence of setting. The first
requirement demands a well -developed sense of intuition; the second, a keen
eye. I ntuition, like mine sense, is gained through experience and an
understanding of the enemy's techniques and habits. A keen eye is the result
of training and practice in the recognition of things that might indicate the
presence of a trap. The presence of booby traps or nuisance mines is indicated
by-

• Disturbanceof ground surface or scattered, loosesoil.

• Wrappers, seals, loose shell caps, safety pins, nails, and pieces of wire
or cord.

• Improvised methods of marking traps, such as piles of stones or marks
on walls or trees.

• Evidence of camouflage, such as withered vegetation or signs of
cutting.

• Breaks in the continuity of dust, paint, or vegetation.

• Trampled earth or vegetation; foot marks.

• Lumps or bulges under carpet or in furniture.

Detection methods depend on the nature of the environment. I n open areas,
methods used to detect mines can usually detect booby traps. Look for trip
wires and other signs suggesting the presence of an actuating mechanism. In
urban areas, mine detectors are probably of little use. You have to rely on
manual search techniques and, if available, special equipment.

CLEARING METHODS

The method used to neutralize or disarm a trap depends on many things,
including time constraints, personnel assets, and the type of trap. Remember,
a trap cannot be considered safe until the blasting cap or the detonating cord
has been removed from the charge. This is your first objective and is
particularly important for electric traps, which may contain a collapsing
circuit.

Use the safest method to neutralize a trap. For example, if the FD and the
detonating cord are accessible, it is usually safer to cut the detonating cord.
This method does not actuate the trap, but inserting pins in the FD might.

Booby Traps and Expedient Devices 13-15

C2, FM 20-32

COMBAT CLEARANCE

Clearing booby traps and nuisance mines in AOs is done primarily by
engineers. Therefore, engineer advice is important during the planning stages
of any operation where booby traps are likely to be encountered. I ntelligence
regarding the possible presence and types of traps must be provided to
engineer units as soon as possible. This allows the unit to take necessary
action and provide relevant training. Clearance of booby traps cannot be
undertaken as a secondary task, because engineer clearing teams might
require protection that necessitates combined arms training. Before engineer
planning can start, the staff provides commanders with the latest intelligence
information and, if possible, the following information:

Amount of clearance required.

Acceptable damage.

T i me requ i rements.

Availability of special equipment.

Security requirements.

I ntelligence information regarding the nature, type, and location of traps has
a direct bearing on the number of clearing parties necessary and the degree of
protection required. For example, in built-up areas where traps have to be
cleared in buildings that offer protection from enemy fire, direct protection is
usually provided by the normal combat situation. On the other hand, in open
areas where clearing parties may be required to clear traps covered by direct
enemy fire, protection arrangements must be more specific.

Engineer commanders must be aware of the time needed to clear various
types of traps in differing terrain situations. Remember, increasing the
number of clearance parties may not necessarily reduce the time required to
clear traps. This is particularly true when traps are set close together or set
deep along a narrow front that is the only available route.

I nitially, clear areas of immediate tactical importanceand traps that present a
specific threat. For example, clear only the portion of a building required for
observation and those traps presenting an immediate hazard. This enables
clearing parties to concentrate on other areas of tactical importance.

Clearing traps by hand is the only way that damage can be avoided and
security guaranteed. When it is vital to avoid equipment or structure damage,
consider using available EOD assets. It is often necessary to balance the
requirement to remain silent and avoid damage with the requirement to
maintain momentum.

When traps are being cleared in direct-support combat situations, they are
normally dealt with by using unit resources and locally manufactured or
acquired aids. Specified equipment is rarely available. Equipment varies with
the situation but usually consists of selected items from Table 13-2. I n areas
with a high incidence of booby traps, assemble and reserve special clearing
kits.

13-16 Booby Traps and Expedient Devices

FM 20-32

Table 13-2. Clearing equipment

Item

Remarks

Unit Equipment

Mine detector

Mine probe/knife/bayonet

Eye protection

Body armor

Flak jacket, Kevlar helmet

Booby-trap signs

Mine marking tape

Mine markers

Chalk, felt-tipped pens

Electrician's adhesive tape

Flashlight

Tape measure

Mine marking cones

Trademan's tools

Saws, pliers, hammers, screwdrivers

Self-developing camera
and film

Locally Manufactured/Acquired

Trip-wire feeler

Grapnel and rope

Hand mirrors

Pins, wire, nails

For use as safety pins

Meat hooks

For use as block and tackle

CLEARANCE IN SECURE AREAS

Policy and Planning

Formal clearing procedures must be followed in secure areas. This type of
clearance can be done by engineers or EOD personnel. It is subject to time
constraints when traps or suspected traps are located in urgently required
installations or facilities, such as supply dumps or telecommunication centers.

Commanders reconnoiter their areas of responsibility, make detailed plans,
prepare orders, and brief their men. The following points are covered:

Intelligence.

How the operation is to be conducted (include acceptable damage and
methods of clearing).

Action on finding traps.

Marking.

Disarming procedures.

Tasking and allocation of areas.

Equipment available.

Control measures.

Booby Traps and Expedient Devices 13-17

FM 20-32

Control Point

T i me requ i rements.

Rehearsal and equipment preparation.

The operation commander establishes a control point upon arrival at the area
to be cleared. The control point functions as the headquarters and the
material holding area. It is also the point from which all clearance starts. Its
suitability might not have escaped the enemy's notice, so it must be cleared
before it can be used.

Control and Size of Parties

Marking

The size of clearing parties varies depending on the location being cleared.
The following rules apply:

• Each party is controlled by an N CO.

• Only one party works in a particular subarea.

• The distance between parties is sufficient so that detonation in one
area does not endanger persons in other areas.

• The NCOIC of each party is in visual, radio, or voice contact with
every person in his party.

• Only one person works on a booby trap.

Booby traps and nuisance mines can be placed in diverse locations. It is
impossible to standardize a method for marking areas, individual traps, or
safe routes. Any form of prominent, permanent marking can be used.

Uncleared Areas

The perimeter marking of uncleared areas can take any clearly recognized
form. Standard minefield or booby-trap signs suspended from a single-strand
fence are recommended. The spacing of the signs is the same as standard
minefield marking (see Chapter 2). As the area is cleared, the fence should be
progressively moved.

Individual Traps

Because booby traps can have more than one means of actuation, do not
attempt to place a cone or other marker over any part of a trap. Use sufficient
signs to ensure that the trap can be detected and accurately located. I n
buildings, clearly mark rooms containing traps and, where possible, indicate
the exact location of traps.

Internal Marking

The internal marking system depends on the area being cleared. One good
system is to divide the total area into subareas, clear and mark safe lanes
between the subareas, and then use the lanes as safe routes.

Clearing of Open Areas

Roads, road shoulders, bridges, obstacles, and other structures must be
cleared in open areas. The main threat comes from nuisance mines, so regard

13-18 Booby Traps and Expedient Devices

FM 20-32

each potential site as a nuisance minefield and use established minefield
clearing procedures. After the site is cleared, adapt the drill to suit the
situation.

Clearing of Buildings

Buildings are excellent locations for booby traps. Booby traps are concentrated
inside the building, so carefully organize search and clearing procedures. I n
most cases, buildings are required for use, and excessive damage must be
avoided.

A two-man clearing party can clear an average-size structure. No one else
should enter the building until it is cleared. I n very large buildings, two or
more parties can be employed, if they work as far apart as possible and have
clearly defined boundaries. As a general rule, two walls or two floors is the
minimum distance between parties.

Exterior Reconnaissance and Entry

Before approaching a building, check the surrounding area for booby traps
and nuisance mines. Carry out a reconnaissance to determine the point of
entry and clear the way to it. When selecting the point of entry, consider the
following:

• Doorways. Never consider doorways to be safe unless the door is fully
open and the entrance is clear. If a house is built on a concrete slab, it
is not likely to have a pressureFD in the floor.

• Windows. Windows are excellent locations for booby traps. Pay
particular attention to the ground outside and the floor inside because
they are classic sites for pressure FDs. Use the following procedures if
access must be gained through a window:

— Pull the window if it is unlocked and can be moved. If it is locked,
use a small charge or a heavy object to break the glass.

— Select a stationary window that cannot be opened versus a
window that can be opened when both types are available, because
the window that can be opened is more likely to contain a booby
trap.

— Deal with blinds and curtains in a manner similar to procedures
used for windows.

— Use a mirror to examine inside the window frame before entering
the building.

• Mouseholes. If you decide not to enter the structure through a door or
a window, use explosives to make a mousehole in the wall, roof, or
floor. This offers a remote, safe method of creating an access point, but
it can also detonate nearby traps. Exercise caution if entering through
the roof of a two-story building, because it is far more difficult to clear
booby traps when going down steps than it is when going up them.

Search Techniques

It is impossible to establish a search drill that is suitable for use in all
buildings. It is essential, however, for each working party to develop its own

Booby Traps and Expedient Devices 13-19

FM 20-32

drill and follow it. Domestic dwellings should be searched in the following
order:

1. Floors and furniture.

2. Walls (including doors, windows, fireplaces, and cupboards).

3. Fittings (including light switches and pictures).

4. Ceilings.

Mark each area or item SAFE as it is cleared. This can be conveniently done
by using chalk or a felt-tipped pen.

Use the following techniques and precautions when searching buildings. They
can save your life— learn and remember them!

• Check both sides of a door before opening it. Do this by drilling a hole
through the door and using a mirror to check the other side. You can
also check or open doors by pulling or blowing the lock and hinges with
a small charge.

• Examine floor coverings for signs of disturbance. The presence of FDs
is often indicated by loose floorboards, bulges or tears in carpets, or
loose tiles.

• Use a pulling cableto move furniture and toopen cupboard doors and
drawers.

• Check upholstered furniture and beds by remotely dropping a heavy
object onto them.

• Treat every switch with suspicion, since electrical wiring provides a
ready-made circuit for booby traps. To explode all the traps connected
to the normal power supply, disconnect the power at the fuse board,
turn all the switches on, and then reconnect the power. Repeat the
procedure with the switch turned off in case the switch has been
reversed. Remember, this procedure will not disclose traps that use a
battery. Exercise caution when using switches, even if the power is
disconnected.

Leave doors, windows, cupboards, and drawers open after they have
been cleared.

Mark all routes, areas, and items that have been cleared.

Check plumbing by remotely turning on all water taps and allowing
the water to run for at least one minute.

Check toilet tanks before flushing.

Beware of light-sensitive devices in dark places (closets, cabinets,
basements, attics, chimneys).

Allow at least 30 seconds for an explosion after pulling anything,
because there might be a delay fuse.

13-20 Booby Traps and Expedient Devices

FM 20-32

Clearing Installations and Facilities

Clearing by hand is necessary in installations and facilities (fuel dumps,
ammunition dumps, electric substations) where an explosion could result in
the loss of resources. I n other situations, the item's importance or the
resulting damage might not be obvious. For example, a small charge placed
against the control valves of a dam or against the main cable entering a
telephone exchange results in unforeseen damage that can take days to repair.
Therefore, you should seek a specialist's advice, if possible, when clearing
booby traps in industrial areas and unfamiliar locations.

Clearing Obstacles

If an enemy has time to create obstacles, he also has time to set booby traps
and lay nuisance mines. The obstacle itself is usually clear of traps to
encourage a false sense of security and lead troops i nto more dangerous areas.
Therefore, regard all obstacles as booby-trapped until proven otherwise. The
simplest, safest way to deal with movable obstacles is to pull them. Before an
obstacle can be pulled, you must first clear the area from which the pull will
be made.

Clearing Secure Areas

When clearing secure areas and time is not a major factor, use specialized
clearance equipment as much as possible. The following equipment might be
available for use:

• Cameras. Cameras have a wide range of applications. They can be
used with different types of film, such as infrared and ultraviolet, to
disclose evidence that is indiscernible to the naked eye. For example,
infrared photography reveals differences in the heat emitted by
objects and can often disclose recent digging and buried or concealed
objects.

• Explosive detector dogs (EDDs). Although EDDs can detect minute
quantities of explosives and the presence of trip wires, they are
trained to detect the charge and not the FD. This extremely limits
their usefulness in detecting booby traps. They also tend to become
confused if the area contains explosive odors other than those emitting
from booby traps.

• Electronic countermeasures. Electronic countermeasures can be used
to explode electric booby traps and to prevent remotely controlled,
improvised explosive devices from being detonated by radio.

• Robots. In their simplest form, robots can be used to detonate or
neutralize booby traps. More sophisticated models can be remotely
controlled to carry out simple tasks, such as videotaping or cutting
wires.

• Body armor.

• Electric meters.

• X-ray equipment.

Booby Traps and Expedient Devices 13-21

C2, FM 20-32

CLEARANCE METHODS

Pulling. This method uses a grapnel and a rope to pull the trap. It is
used when the resulting damage is acceptable. It is the safest method
and is particularly applicableto traps set in open areas. Do not disturb
any part of a booby trap when placing the grapnel and pulling the
cable. Carefully select the site from where the pull is to be made
because it might be mined or trapped. When a booby trap is pulled and
does not explode, wait at least 30 seconds before approaching it in case
delay devices have been used. Disposal of unexploded traps depends
on their condition when inspected. The procedure for pulling booby
traps is similar to that for pulling mines (see Chapter 11).

Trip wires. Check the area for AP devices before proceeding. Place a
grapnel hook as close as possible to the trip wire. Do not touch the trip
wire until the pulling party is in a covered area.

Pull and release. Pull away objects that conceal and operate pull and
release mechanisms.

Pressure mechanism. Pull pressure mechanisms from under objects
that conceal and operate them. If this is impossible, blow them in
place. In many cases, it might be easier to pull the charge rather than
the FD. Take extreme care when attempting this, because additional
mechanisms are often concealed in or under the main charge.

Destroying in place. When destroying booby traps in place, explode a
small charge near the booby trap's charge. Again, use this method only
if damage from the explosion is acceptable. When it is impossible to
place the explosive close enough to ensure detonation of the main
charge, carefully place it alongsidethe mechanism. Do not assume the
main charge is safe to handle just because the mechanism has been
destroyed. Actuate pressure mechanisms by suspending one-half
pound of explosive above the pressure plate.

Clearing by hand. This method involves neutralizing, disarming,
removing, and disposing of traps without causing damage. It is
extremely hazardous and should only be used when pulling or
destructing traps in place is impossible or unacceptable. Clearance
should only be conducted by EOD personnel or experienced engineers.
Carefully examine all aspects of the trap before deciding how to clear
it.

Explosive line charge. Using this device produces quick results when
only a narrow path is required through a booby-trapped area. It gives
clearance for the same distance to either side, only where it is in
contact with the ground.

Armor. This method is used where traps with small charges (designed
as AP devices) are located in open areas. Armored vehicles track back
and forth over the area. This shortens the clearing time with little risk
of casualties.

13-22 Booby Traps and Expedient Devices

FM 20-32

Fire. If traps are set in grass or dense vegetation, fire can be used to
burn away camouflage material and expose traps. In most cases,
sufficient heat is generated to burn or explode the traps. Unexploded
traps are considered extremely sensitive and must not be cleared by
hand.

IMPROVISED TRAPS

I n low-intensity conflicts, there is a high incidence of improvised mines and
booby traps. It is impossibleto provide a complete list of FDs and improvised
demolition material that can be used. However, most improvised traps are
variations of those described below.

An electric FD requires a current to be passed between two contacts. The ways
in which this can be achieved are limited only by the imagination. Examples of
simple electric FDs that can be manufactured using household items or
appliances are shown in Figure 13-6, page 13-24. Examples of improvised
mechanical FDs are shown in Figures 13-7 and 13-8, page 13-25.

The simplest and most accurate method of incorporating delay is to use some
form of clock or timer. However, any mechanism or chemical reaction that
takes a measurable time to complete its function can be used. Examples of
simple improvised delay devices are shown in Figures 13-9 and 13-10, page
13-26.

NONEXPLOSIVE TRAPS

PUNJ

Closing Trap

Nonexplosive traps are typically used in tropical or rain-forest regions. Ideal
construction materials abound, and concealment in surrounding vegetation is
relatively easy. No prescribed procedures exist for clearing nonexplosive traps.
E ach trap must be cleared accordi ng to its nature.

The punji (Figure 13-11, page 13-27) is one of the simplest traps. It is
normally made from locally available material, such as sharpened stakes,
nails, or heavy-gauge wire. It is placed in concealed pits or in places that give
cover from fire. The enemy normally smears the spikes or cutting edges with
excrement or poison. After clearing a punji, sterilize cuts and abrasions
immediately and see a medical officer as soon as possible.

The side-closing trap (Figure 13-12, page 13-27) consists of two wooden slats
that are studded with spikes. The slats slide along a pair of guide rods
controlled by heavy bands. When the prop holding theslats apart is dislodged,
the slats spring together and implant the spikes into the portion of the body
passing between them.

Booby Traps and Expedient Devices 13-23

FM 20-32

Tension release

Tension release

Gravity

Figure 13-6. Improvised electrical FDs

13-24 Booby Traps and Expedient Devices

FM 20-32

Copper shear pin

NOTE: An improvised percussion cap
assembly consists of a small-arms
round and a nonelectric blasting cap.

Metal tube

Nail

Improved percussion-
cap assembly

Pressure board

Figure 13-7. Improvised nonelectric FDs (shear-pin operated)

Metal tube

Bolt stem and nut
Shear pin

Release pin

Improved percussion-
cap assembly

Figure 13-8. Improvised nonelectric FDs (spring-operated)

Booby Traps and Expedient Devices 13-25

FM 20-32

Battery

Electric blasting

Thin spring steel
contact

Leads to battery and electric
blasting cap

Figure 13-9. Improvised, electric delay devices

Time fuse

Fuse train

Pin-release device

Figure 13-10. Improvised, nonelectric delay devices

13-26 Booby Traps and Expedient Devices

FM 20-32

Punji foot trap

Punji board

Figure 13-11. Typical punjis

$&&>£&

Figure 13-12. Side-closing trap

Booby Traps and Expedient Devices 13-27

FM 20-32

Spike Board

The spike board (Figure 13-13) is used in a pit and consists of a treadle board
with one end spiked. When a man steps on the board, the spiked end flies up
and strikes him in the face or chest.

Venus Flytrap

Figure 13-13. Spike board

The Venus flytrap consists of a rectangular framework with overlapping barbs
emplaced in a pit. The one shown in Figure 13-14 is made from a metal
container that is sunk into the ground until the top is flush. It is then covered
with grass and/or leaves. The barbs inflict injury, especially when the victim
attempts to withdraw his leg from the trap. These traps are typically located
on tracks and along road edges.

Figure 13-14. Venus fly trap

13-28 Booby Traps and Expedient Devices

FM 20-32

Section III. Expedient Devices

Expedient devices are constructed in the field with locally available material.
They are employed against vehicles or personnel in the same manner as other
mine systems. Expedient devices—

• Supplement a unit's low supply of conventional mines.

• Hinder reconnaissance, clearance, and neutralization of minefields.

• Create enemy attitudes of uncertainty and suspicion to lower morale
and slow movement).

AUTHORIZATION

Because expedient devices have nonstandard design and functioning, take
special precautions to protect friendly forces. Consider neutralization,
disarming requirements, and adequate marking procedures. The use of
expedient devices is restricted under the Convention of Conventional Warfare.
Expedient devices have the same international restrictions as booby traps.
The corps commander is the employment authority for expedient devices. He
can delegate this authority to the division commander. If authority is given to
use expedient devices, US personnel will adhere to the rules for international
law that are applicable to armed conflict.

EMPLOYMENT AND CONSTRUCTION TECHNIQUES

If issued mines are not readily available on the battlefield, expedient devices
can be manufactured in the field. Construction varies based on available
materials and the ingenuity of the personnel who are fabricating the devices.
Expedient devices posea potential safety hazard to friendly forces— those who
are constructing them and those who may later encounter them. Construction
should be performed by personnel who are familiar with the materials being
used. I nnovative designs should be checked and tested before arming and
emplacing the devices.

As a minimum, test the fusing mechanism separately to ensure that it
functions as designed. I mproper fuse operation is the most common cause of
malfunction. Also, test thefuseand the firing chain (base charge, blasting cap,
and detonating cord) without the main charge to ensure proper operation.
Empl ace the device after satisfactory performance of the firing mechanism.
First, empl ace heavy items (such as artillery shells) that are used as the main
charge, and then add the firing mechanism. Take care when moving or
emplacing expedient devices because their nonstandard manufacture and
potentially faulty construction make them highly sensitive to jars and shocks.
Construct devices at the emplacement site whenever possible.

Expedient devices are prepared in the field using standard US FDs,
detonators, and demolition materials. All devices discussed in this chapter can
be made to function electrically or nonelectrically using modernized
demolition initiators (MDIs). AP devices must be command-detonated.

Booby Traps and Expedient Devices 13-29

C2, FM 20-32

High-Explosive, Artillery-Shell Device

The HE, artillery-shell device (Figure 13-15) can be readily adapted to
expedient mining. Remove the artillery fuse and replace it with a standard FD
and a length of detonating cord or with an M Dl blasting cap. If properly
assembled, a destructor may also be used. If a destructor is not available,
firmly pack the fuse well with composition C4 explosive and insert a length of
knotted detonating cord or a blasting cap.

PRESSURE FD WITH
DESTRUCTOR

Standard base

Nonelectric
blasting cap

\

M142 multi- T F

M10 universal
destructor

M142 multi-
purpose FD

Pull FD with
C4 explosive

Priming adap

artillery shell
with fuse
removed

Standard base cap
(remove)

Standard base

Nonelectric
blasting cap

C4 explosive

\

Standard base cap
(remove)

Artillery shell
with fuse
removed

gEp FI with fuse

Detonating cord

ELECTRICAL
FIRING SYSTEM

Metal plates

A

Paper or suitable
insulating material

Electric
^blasting cap

!r-

Composition C4
explosive

Artillery shell
with fuse
removed

Power system

NOTE: For command-detonation, an M34 blasting
machine can replace the metal plates and the battery.

Electric-cap leads

Figure 13-15. HE, artillery-shell device

The device can be activated by a variety of methods depending on the type of
FD used. When MDI blasting caps are used, the device is command-detonated.
The device can also be adapted to function electrically by adding an electric
cap and a power source.

This device can be used as an AT or an AP device. When used as an AP device,
it must be command-detonated.

NOTE : Use only serviceable US ammunition that has remained in the
possession of US forces. Never use captured ammunition or UXO
found on the battlefield. It may be armed, booby-trapped, or
deteriorated.

13-30 Booby Traps and Expedient Devices

C2, FM 20-32

Platter Charge

The platter charge (Figure 13-16) consists of a suitable container that is filled
with uniformly packed explosive and placed behind a platter. The platter is
metal (preferably round, but square is satisfactory) and weighs 1 to 3
kilograms. The explosive required is equal to the weight of the platter. The
container may not be necessary if the explosive can be held firmly against the
platter (tape can be used). The charge should be primed from the exact rear
center, and the blasting cap should be secured with a small amount of C4 to
ensure detonation.

To initiating device
(electric or
nonelectric)

Blasting cap (electric or
nonelectric) primed in
center rear of explosive

C4 explosive
main charge

Center of target

Platter

Figure 13-16. Platter charge

The charge should be aimed at the direct center of the target. The effective
range (primarily a matter of aim) is approximately 35 meters for a small
target. With practice, experienced personnel can hit a 55-gallon drum (a
relatively small target) at 25 meters with about 90 percent accuracy.

The platter charge can be used as an AT or an AP device. When used as an AP
device, it must be command-detonated.

Improvised Claymore

For the improvised claymore device (Figure 13-17, page 13-32), a layer of
plastic explosive is attached to the convex side of a suitably dense, curved base
(such as wood or metal). A hole must be made in the exact rear of the base. A
blasting cap is placed in the hole to prime the device. Shrapnel is fixed to the
explosive with a suitable retainer (cloth, tape, mesh screen).

The device must be command-detonated. Command detonation is best
achieved with electrical priming or an MDI. A blasting device is attached to
the electric cap via firing wires laid at least 50 meters from the device. Ensure
that personnel have adequate cover when detonating the improvised
claymore.

Booby Traps and Expedient Devices 13-31

C2, FM 20-32

Screen or
retainer

Shrapnel

Convex base

Explosive ( 1 /4 weight of shrapnel)

Enemy

Electric blasting cap primed in
'center with C4 wadding

m
(minimum)

Blasting machine (or
suitable substitute)

Figure 13-17. Improvised claymore device

Grapeshot Antipersonnel Device

Place shrapnel in the bottom of a cylindrical container to make a grapeshot
AP device (Figure 13-18). The shrapnel is tamped and held in place with a
suitable separator (wadding). Explosive (approximately one-quarter the
weight of the shrapnel) is packed to a uniform density behind the wadding.
The device is primed in the center of the explosive with an electric cap or an
MDI.

NOTE : The United Nations Convention of Certain Conventional
Weapons mandates that all fragment munitions produce fragments
that are visible by X ray (such as metal or rock).

This device must be command-detonated. The explosive propels the shrapnel
outward from the container. The grapeshot is very effective against personnel
targets.

Barbwire Antipersonnel Device

The barbwire AP device (Figure 13-19) can be made directional by placing the
wire against an embankment or a fixed object. This causes the force of the
explosion to expel the barbwire fragments in the desired direction. One roll of
standard barbwire is placed into position, and one block of C4 is placed in the
center of the roll and primed. This device must be command-detonated.

13-32 Booby Traps and Expedient Devices

C2, FM 20-32

<^> Wadding Shrapnel

xplosive ( 1 /4 weight of
hrapnel)

Container

C4 explosive

Primed in
center

Blasting machine

Bottom

Electric
blasting cap

Wadding Shrapnel

Figure 13-18. Grapeshot AP device

M34 blasting machine ^___ _^~^

(or suitable substitute) w^^vTM

Electric blasting cap

1 1 /4-lb block of C4

Roll of barbwire "* ~~ ""o

Figure 13-19. Barbwire AP device

Booby Traps and Expedient Devices 13-33

FM 20-32

13-34 Booby Traps and Expedient Devices

Appendix A

Installation and Removal of US Mines
and Firing Devices

This appendix provides installation and removal procedures for AT mines,
AP mines, and FDs. The scope of this appendix is limited to US hand-
emplaced mines that require manual arming.

WARNINGS

1. If there is a problem when performing any installation or removal step, notify the NCOIC.

2. If you hear a click when removing the safety clip or if the pressure plate snaps downward
so it is level with the body of the mine, notify the NCOIC. DO NOT use the mine.

3. If the safety clip cannot be reinserted, notify the NCOIC.

4. DO NOT apply pressure to the pressure plate, tilt rod, or fuse at any time.

5. Before attempting to disarm and remove the mine, check for AHDs, damage, and
malfunctions. If any of these conditions exist, notify the NCOIC. DO NOT attempt to disarm
the mine.

6. If you feel a jar or hear a metallic click when removing the locking safety pin, stop and
notify the NCOIC. The firing pin has gone forward and is resting on the positive safety pin.
DO NOT remove the positive safety pin.

7. After removing the positive safety pin, proceed with extreme caution. The slider pin can
detonate the mine if it is accidentally pushed in.

8. When attaching trip wires to the release-pin ring on the fuse, leave a little slack in the
wires. This prevents pull on the release-pin ring, which could set off the mine when the
safety pins are removed.

9. Ensure that the extension rod is vertical and is not tilted in any direction. A 20-degree tilt
of the extension rod will detonate the mine.

10. Ensure that the safety fork moves freely. If there is pressure on the fork, DO NOT remove
it.

11. DO NOT apply pressure to the pressure plate of the fuse when inserting it into the fuse
well.

12. If the setting knob is difficult to turn, DO NOT force it; notify the NCOIC.

13. DO NOT adjust the setting knob while the detonator is in the detonator well.

14. If any cracks are noted in the plastic collar, slowly and carefully reassemble the stop
and safety pin on the fuse. Carefully remove the extension rod and the fuse from the mine.
Give the fuse to the NCOIC and replace it with a new fuse.

15. Before cutting loose trip wires, look at each end to ensure that there are no electric-
producing devices that might initiate another system.

16. Arm and disarm all mines while in the prone position.

Installation and Removal of US Mines and Firing Devices A-1

FM 20-32

Section I. Antipersonnel Mines

M14

AP mines can kill or incapacitate their victims. They can be fused by pressure,
wire, or command detonation and contain a blast, bounding-fragmentation, or
direct -fragmentation warhead.

The M 14 mine (Figure A-l) is a low-metallic, blast AP mine. It has a plastic
body and an integral plastic fuse with a steel firing pin.

Indicating
arrow

Pressure plate

Fuse body

Belleville
spring

Carrying cord

Firing pin
Mine body / Detonator

Detonator holder

Figure A-1. M14 AP mine

Characteristics

Main Charge

Diameter

Height

Weight

No Mines per Box

Weight per Box

Tetryl, 28.4 g

56 mm

40 mm

99.4 g (fused)

90

19.8 kg

• Korea Only: The M14 is employed in tactical and nuisance
minefields.

• The M14's size allows for employment in large numbers, and rapid
concealment is possible.

• The M14 is buried to prevent the target from knocking it over.

A-2 Installation and Removal of US Mines and Firing Devices

FM 20-32

The M 14 is not designed to kill but to penetrate a boot or a foot.

The M14 is difficult to detect because of plastic construction.

The M14 requires an operating force of 11.5 to 13.5 kilograms to
activate.

Installation

WARNING
Emplace and remove the mine while in the
prone position.

Inspect the mine.

— Do not usethemineif it is dented, cracked, or damaged.

— Use the M22 wrench (Figure A-2) to remove the shipping plug
from the detonator well.

Use to remove the plug or
the detonator holder.

Use to turn the pressure plate.

Figure A-2. M22 wrench

— Inspect the position of the firing pin. Do not use the mine if the
firing pin extends into the detonator well.

— I nspect the detonator well for foreign material. If foreign material
is present, remove it by carefully tapping the mine against the
palm of your hand. If you cannot remove the debris, replace the
shipping plug and do not use the mine.

Test the pressure plate.

— E nsure that the arrow is in the SAFE position.

— Use the M22 wrench to turn the pressure plate from the SAFE
position tothe/\/RMED position (Figure A-3, pageA-4).

— Grasp the mine in one hand and remove the safety clip with the
other hand. Listen for a click, indicating that the firing pin has
dropped. Recheck the fuse well (Figure A-4, pageA-4).

— Replace the safety clip.

Installation and Removal of US Mines and Firing Devices A-3

FM 20-32

Use the M22 wrench to turn the pressure plate back to the SAFE
position.

Figure A-3. M14 mine in ARMED position

Pull cord

Indicating arrow

Carrying cord

Figure A-4. Removal of safety clip

Ensure that a metallic washer is attached (glued) to the bottom of the
mine. If a washer is not attached, notify the NCOIC and do not use
the mine. Apply silicone on the outside of the washer to prevent water
damage, and screw the detonator into the well on the bottom of the
mine (Figure A-5). NOTE : Ensure that the gasket is tightly
wedged between the detonator and the washer and that the
washer is properly seated between the gasket and the body of
the mine so that water cannot enter the mine.

Dig a holetofit the mine.

A-4 Installation and Removal of US Mines and Firing Devices

FM 20-32

Removal

Detonator

Lot number

Date loaded
(month/year)

Figure A-5. Bottom view of M14 mine

— Dig a hole approximately 10 centimeters in diameter and deep
enough (approximately 3.5 centimeters) so that the pressure plate
extends above the ground.

— Inspect the ground at the bottom of the hole.

> Ensure that the ground is hard enough to support the mine
when pressure is applied to the pressure plate.

> Place a flat object in the bottom of the hole for the mine to rest
on if the ground is too soft. Allow additional depth for the
objects.

• Arm the mine with an M22 wrench by turning the pressure plate to
tbeARMED position.

• Place the mine in the hole.

• Remove the safety clip carefully, while holding the mine body firmly in
the hole.

• Camouflage the mine.

• Disarm the mine.

— Clear the soil away from the mine carefully.

— Grasp the body of the mine firmly with one hand, and insert the
safety clip with the other hand.

— Use the M22 wrench to turn the pressure plate to the SAFE
position.

• Remove the mine from the hole.

— Turn the mine over, and carefully remove the detonator from the
detonator well.

— Screw the shipping plug into the detonator well.

— GivethedetonatortotheNCOIC.

Installation and Removal of US Mines and Firing Devices A-5

FM 20-32

M16

The M16-series mine (Figures A-6, pageA-6) is a bounding-fragmentation AP
mine. Once actuated, the mine is propelled out of the ground (to a height of
approximately 1.8 meters) and explodes. The mine consists of an M 605 fuse, a
propelling charge, and a projectile that are contained in a sheet-steel case.
The fuse is screwed into the top of the case and extends through the center of
the projectile to the bottom of the case, where the propelling charge is located.
The remaining space inside the case is occupied by the projectile. Earlier
versions of the mine are also available for issue. The principal difference
between the old and new versions is the construction of the detonators and
boosters.

Fragmentation
shell (body)

199 mm

MINE /,$

RSONNELM

Hi

.■■ass-

103 mm

Main charge

Booster
charge

,Detonator

-Primer mixture
Delay

element

Propelling charge

Figure A-6. M16A1 AP mine

Characteristics

Main Charge

Diameter

Height

Weight

No Mines per Box

Weight per Box

TNT

103 mm

199 mm

3.5 kg

4

20.25 kg

• Korea Only: The M16 is employed in protective, tactical, and
nuisance minefields.

• The M16 is used to defeat dismounted assaults and breaching
operations.

• The M 16 is pressure-actuated (3.6 to 9 kilograms) or pull-actuated (1.4
to 4.5 kilograms).

A-6 Installation and Removal of US Mines and Firing Devices

Installation

FM 20-32

The M 16 and M 16A1 have a casualty radius of 27 meters; the M 16A2
has a casualty radius of 30 meters. The danger radius for friendly
forces is 183 meters for all M 16 mines.

WARNING
Emplace and remove the mine while in the
prone position.

Inspect the mine.

— Do not usethemineif it is dented, cracked, or damaged.

— Use the closed end of an M25 wrench to remove the shipping plug
from the fuse well (Figure A-7).

Shipping plug

M25 wrench

^

A16A1 mine

Figure A-7. M16A1 mine and M25 wrench

— Inspect the fuse well for foreign material. If foreign material is
present, turn the mine upside down and gently tap the bottom
with your hand to dislodge the material. If you cannot remove the
debris, replace the shipping plug and do not use the mine.

— Examine the fuse assembly carefully for evidence of damage or
missing safety pins. Ensure that the safety pins move freely in
their holes and that the rubber gasket is around the fuse base
(Figure A-8, pageA-8).

Installation and Removal of US Mines and Firing Devices A-7

FM 20-32

Interlo
Locking safety pin _

eking safety pin

\ Pressure
— prongs

Mrs '£

-y^i~

(

( c

Positive
safety pin

r

Flash igniter

-m

Rubber
gasket

Release-pin
ring

Figure A-8. M605 fuse

WARNING
DO NOT use any fuse that was manufactured
before 1957.

• Fuse the mine.

— Use the open end of the M25 wrench to tighten the bushing
adapter on the fuse wel I .

— Screw the fuse assembly into the fuse well by hand and tighten
the assembly with the M 25 wrench. Ensure that the rubber gasket
is between the fuse body and the bushing adapter. NOTE: For
long-term use, smear a thin layer of silicone grease or
similar lubricant on the fuse and threads.

• Dig a holetofit the mine.

— Pressure installation. Dig the hole so that only the pressure-prong
tips are above ground level.

— Trip-wire installation. Dig the hole so that the release-pin ring is
above ground level.

• Empl ace the mine.

— Place the mine in the hole and ensure that the safety pins remain
in place.

— Cover the mine with soil to the bottom of the release-pin ring.

— Press the soil firmly around the sides of the mine.

Pressure I nstallation

Remove the locking safety pin (Figure A-9). The interlocking safety
pin will come free.

A-8 Installation and Removal of US Mines and Firing Devices

FM 20-32

Positive safety pin

Interlocking safety pin

Locking safety pin

Trip-Wire Installation

Figure A-9. Safety pins

Arrange the pull cord on the positive safety pin so that it withdraws
easily. Remove the metal collar.

Finish covering the mine with soil until only the pressure prongs are
above ground level.

Camouflage the mine, place excess soil in sandbags, and remove
sandbags from the area.

Arm the mine by removing the positive safety pin (Figure A-9).

Givethe safety pins and theshipping plug tothe NCOIC.

Install the trip wire (Figure A-10).

jL. Enemy side

WW

'• ."j ~ '■■-■'

• .*;■• '.\'.7 *-. . * . i. ' ... i ..i-m 'T . i

Figure A-10. Buried mine with a trip wire

Installation and Removal of US Mines and Firing Devices A-9

FM 20-32

Cover the mine with soil and press it firmly around the sides of the
mine. Leave the release-pin ring and the pressure prongs exposed.

Tie off trip wires, approximately 10 meters from the mine. The wires
should form a wide V, with the opening toward the enemy.

Attach trip wires to the release-pin ring on the fuse.

Remove the locking safety pin. The interlocking safety pin will come
free.

Arrange the pull cord on the positive safety pin so that it withdraws
easily.

Camouflage the mine, place excess soil in sandbags, and remove
sandbags from the area.

Arm the mine by removing the positive safety pin.

Givethe safety pins and theshipping plug tothe NCOIC.

Removal

WARNING
Before attempting to disarm and remove the mine,
ensure that the metal collar (Figure A-11) over the
top of the striker on the M605 fuse is in place.

I' >*"

Metal collar

Figure A-11. Metal collar on an M605 fuse

A-10 Installation and Removal of US Mines and Firing Devices

C2, FM 20-32

• Disarm the mine.

— Clear the soil carefully from the top of the fuse to the positive
safety-pin hole. When using the M605 fuse, clear away all the soil
from the fuse area.

— Insert the positive safety pin through the positive safety-pin hole.

— I nsert the locking safety pin through the locking safety-pin hole.

— Cut the slack trip wires that are attached to the release-pin ring.

• Check for AH Ds.

— Hold the mine body firmly in place with one hand.

— Feel for AHDs with the other hand by digging around the sides of
and underneath the mine.

• Remove the mine.

— Remove the mine from the hole. Ensure that the safety pins
remain in place.

— Remove the M 605 fuse with the M 25 wrench.

— Replace the shipping plug in the fuse well.

Section II. Antitank Mines

M15

AT mines are designed to immobilize or destroy tanks and vehicles and their
crews. They perform this function by producing an M-Kill or a K -K ill. An M-
Kill is achieved by destroying one or more of the vehicle's vital drive
components (usually breaking the track on a tank), causing the target to be
immobilized. The weapon system and thecrew are not destroyed in an M-Kill;
the weapon system is immobile but continues to function. A K-Kill results
when the weapon system or the crew is destroyed.

Conventional AT mines are distinguished by their effects and their fusing
systems. Blast AT mines, such as the M 15 and M 19, derive their effectiveness
through the blast generated by their detonation. These usually produce an M-
Kill, but a K-Kill may result. Mines such as the M21 use a shaped charge or
an SFF designed to penetrate the underside of a vehicle's armor. A K-Kill
normally results unless the mine detonates under the vehicle's track.

The M 15 (Figure A-12, page A-12) is a blast AT mine that is contained in a
round sheet-steel casing. The primary fuse well is located in the top center of
the mine. There are two secondary fuse wells— one on the side and one on the
bottom. The primary fuse well accepts the M603 pressure-actuated fuse.
Standard FDs can be used in the secondary fuse wells with the Ml activator.
The M 624 tilt-rod-actuated fuse can also be used with this mine.

Installation and Removal of US Mines and Firing Devices A-11

C3, FM 20-32

337 mm

125 mm

Arming plug in
SAFE position

Pressure plate

Fuse retainer spring

Secondary
fuse well

Arming plug

Gasket

Secondary
fuse well

Pressure plate

Filling hole

NOTE: Inspect secondary fuze wells for corrosion. Do not fit an
M1 activator into a corroded fuze well. In training, return any
mine with a corroded fuze well to the ASP as unserviceable.

Secondary
fuse well

Figure A-12. M15 AT mine

Characteristics

Main Charge

Diameter

Height

Weight

No Mines per Box

Weight per Box

Comp B, 9.9 kg

337 mm

125 mm

13.5 kg

1

18 kg

• The M 15 is employed in protective, tactical, and nuisance minefields.

• The M 15 is surface-laid or buried.

• The M 15 requires a force of 158 to 338 kilograms to detonate the M 603
fuse and a force of 1.7 kilograms to deflect the tilt rod and detonate the
M 624 fuse.

• The M 15 is designed to defeat heavy tanks.

• The M15 produces an M-Kill upon contact.

A-12 Installation and Removal of US Mines and Firing Devices

FM 20-32

Installation Using the M624Fuse

WARNING
Emplace and remove the mine while in the
prone position.

Inspect the mine.

— Do not usethemineif it is dented, cracked, or damaged.

— Use the M20 wrench (Figure A-13) to remove the arming plug.

Hook end

Tab end

Figure A-13. M20 wrench

— Inspect the fuse well for foreign material. If foreign material is
present, turn the mine upside down and gently tap the bottom
with your hand to dislodge the material. If you cannot remove the
debris, replacethe arming plug and do not use the mine.

— Ensure that the booster retainer ring is seated in the fuse well. If
the retainer ring is missing, replacethe mine.

Inspect the fuse.

— Remove the M624 fuse from the metal shipping container and
inspect it for serviceability.

— I nspect the plastic collar of the fuse by looking down through the
top of the pressure ring. If the safety pin is missing or improperly
assembled, do not use the fuse (Figure A-14, pageA-14).

— Do not usethefuse if the plastic collar appears to be cracked.
Fuse the mine.

— Remove the M 624 fuse from its fi ber sleeve.

— Remove the end closure on the M 624 fuse. NOTE: For long-term
emplacement, coat the fuse threads and gasket with
silicone grease before removing the end closure (Figure A-
15, page A-14).

Installation and Removal of US Mines and Firing Devices A-13

FM 20-32

Figure A-14. Correct safety-pin configuration

Safety stop

Pressure ring

J M624 fuse
^"na") / ..Hole for fuse
■"•""Tyjw^ // tightening

oaieiy uano V%T

Safety pin — y

Gasket" ^^si^*

Th reads -^^ C\ *)

End closure^
//

"^S^^'

Figure A-15. Greasing the M624 fuse

— Screw the fuse hand-tight into the fuse well.

— Remove the extension rod from its packaging.

— Tighten the fuse by inserting the unthreaded end of one extension
rod piece into the hole on the side of the fuse. Turn the fuse a
quarter turn (Figure A-16).

— Remove the extension rod for further use after the fuse is secure.

NOTE : The M15 AT mine (with the M624 fuse) can be buried or
surface-laid. If surface-laid, it must be staked in place.

• Dig a holetofit the mine.

— Dig a hole deep enough sothat thetopof the pressure plate will be
at ground level.

A-14 Installation and Removal of US Mines and Firing Devices

FM 20-32

M624 fuse

Safety pin

Extension-rod
piece /

Tighten
clockwise.

Figure A-16. Tightening the fuse with the extension rod

— Dig the sides of the hole at a 45-degree angle to prevent vehicles
from bridging the mine.

• Empl ace the mine.

— Place the mine in the hole.

— Cover the mine with 2 centimeters of soil (FigureA-17).

Keep debris away
from the tilt rod.

Replaced soil

2 cm

yASy/S.V>TA \^VA.V^^v^7V ' A^

Figure A-17. M15 mine in the hole

NOTE : The M15 AT mine (with the M624 fuse) can be used in the tilt-
rod or pressure role. In the tilt-rod role only, assemble all three
pieces of the extension rod (Figure A-18, page A-16) and thread the
extension rod into the threaded pressure ring of the fuse (Figure A-
19, page A-16).

Installation and Removal of US Mines and Firing Devices A-15

FM 20-32

Extension-rod pieces

Threaded end

Figure A-18. Extension-rod assembly

Extension-rod
assembly

M624 fuse

5 mine

Figure A-19. Assembly of the extension rod into the fuse ring

• Arm the mine.

— Use your right hand to raise the safety pin to the horizontal
position, and grasp the safety band and safety stop with your left
hand. Note the position of thethumb in Figure A-20.

— Remove the safety pin with your right index finger, pulling it to
the right.

— Remove the safety stop carefully while holding the safety band in
place.

— Remove the safety band.

• Camouflage the mine.

— Camouflage the mine with twigs, grass, or other material in the
area. Place mines with extension rods in tall grass, if possible.
Ensurethat no pressure is applied tothetilt rod or thefuse

A-16 Installation and Removal of US Mines and Firing Devices

FM 20-32

Extension rod

Pressure ring

Left hand

Right hand
Safety stop P u n

Safety band

Safety

Figure A-20. Removal of safety pin

— PI ace excess soil in sandbags and remove them from the area.

— Give the band, the stop, the pull-ring assembly, the arming plug,
and the end closuretothe NCOIC.

Removal Using the M624Fuse

• Disarm the mine.

— Clear camouflage away from the mine carefully.

— Assemble the band, the stop, and the safety-pin assembly on the
fuse so that the pressure ring is immobilized.

— Remove the extension rod.

• Check for AH Ds.

— Hold the mine firmly in place with one hand, without putting
pressure on the fuse.

— Feel for AHDs with the other hand by digging around the sides of
and underneath the mine.

• Remove the mine.

— Remove the mine from the hole.

— Remove the fuse from the mine; use the extension rod if necessary.

— Replace the end closure on the fuse.

— Install the arming plug into the fuse well.
Installation Using the M603 Fuse

• Inspect the mine.

— Do not usethemineif it is dented, cracked, or damaged.

Installation and Removal of US Mines and Firing Devices A-17

FM 20-32

— Use the M20 wrench to remove the arming plug from the mine.

— Inspect the fuse well for foreign material. If foreign material is
present, turn the mine upside down and gently tap the bottom
with your hand to dislodge the material. If you cannot remove the
debris, replacethe arming plug and do not use the mine.

— Ensure that the booster retainer ring is seated in the fuse well. If
the retainer ring is missing, replacethe mine.

Perform a function check with the arming plug.

— Turn the setting knob to the ARMED position. Ensure that the
shutter bar moves across the bottom of the arming plug (FigureA-
21)

— Turn the setting knob to the SAFE position. Ensure that the
shutter bar moves back across the bottom of the arming plug
(Figure A-22). NOTE: If the shutter bar does not go into the
SAFE or ARMED position, notify the NCOIC.

Setting knob in
ARMED position

Shutter bar
ARMED position

NOTE: A coil spring may not
be present in older models.

Figure A-21. ARMED position

Setting knob in
SAFE position

Shutter bar in
SAFE position

Figure A-22. SAFE position

A-18 Installation and Removal of US Mines and Firing Devices

FM 20-32

• Fuse the mine.

— Remove the M603 fuse from the metal shipping container and
inspect it for serviceability. The green end of the detonator must
show in the bottom of the fuse.

— Remove the safety fork; use the hooked end of an M20 wrench if
necessary (Figure A-23).

Fuse pressure plate

Safety fork

Figure A-23. Safety fork

— I nsert the fuse into the fuse well carefully until it seats securely
on top of the booster retaining ring.

— Perform a clearance test using the tab end of the M20 wrench
(Figure A-24, pageA-20).

WARNING
If the fuse pressure plate interferes with the tab end
of the M20 wrench, investigate the cause and notify
the NCOIC. DO NOT arm the mine.

NOTE: For long-term emplacement, smear a thin layer of silicone
grease or similar lubricant on the arming plug, the threads, and the
gasket.

— Ensure that the setting knob is in the SAFE position.

— Screw the arming plug intothemineby hand. Ensure a watertight
seal by tightening the arming plug with the M20 wrench.

• Dig a holetofit the mine.

— Dig a hole deep enough so that the top of the pressure plate is
about 3 centimeters below ground level.

— Dig the sides of the hole at a 45-degree angle to prevent vehicles
from bridging the mine (Figure A-25, pageA-20).

• Empl ace the mine.

Installation and Removal of US Mines and Firing Devices A-19

FM 20-32

M20 arming wrench

Figure A-24. Clearance test

3 cm

Figure A-25. M15 mine in the hole

— Place the mine in the hole.

— Cover the mine with soil until it is level with the top of the
pressure plate.

• U se the M 20 wrench to arm the mine by turning the setting knob from
theSAFE position tothe/\RMED position.

• Camouflage the mine.

— Cover the mi ne with 3 to 5 centi meters of soi I .

— Camouflage the mine, place excess soil in sandbags, and remove
sandbags from the area.

— GivethesafetycliptotheNCOIC.
Removal Using the M603 Fuse

• Disarm the mine.

— Clear the soil from thetop of the mine carefully.

— Hold the mine firmly in place with one hand, without putting
pressure on the pressure plate.

— Feel for AHDs with the other hand by digging around the sides of
and underneath the mine.

A-20 Installation and Removal of US Mines and Firing Devices

M19

FM 20-32

— Use the M20 wrench to turn the setting knob to the SAFE
position.

Remove the mine.

— Remove the mine from the hole.

— Use the M20 wrench to turn the arming plug counterclockwise,
and remove the arming plug.

— Remove the M603 fuse from the fuse well and replace the safety
fork.

— Install the arming plug.

The M19 AT mine (Figure A-26) is housed in a square, plastic case and holds
9.45 kilograms of Composition B (HE charge). It consists of an M606 integral
pressure fuse and two secondary fuse wells— one in the side and one in the
bottom. The fuse body contains a pressure plate, a Belleville spring, a setting
knob, a step plate, a firing-pin assembly, and a detonator.

Pressure plate

Setting knob in
SAFE position

Safety clip

Activator-well plug

Safety-clip cord

Carrying-cord
handle

Pressure plate Step plate Belleville springs

M606 integral-
pressure fuse

1

Tetryl booster pellet

Figure A-26. M19 AT mine

Installation and Removal of US Mines and Firing Devices A-21

FM 20-32

Characteristics

Main Charge

Diameter

Height

Weight

No Mines per Box

Weight per Box

Comp B, 9.45 kg

332 mm

94 mm

12.6 kg

2

32.5 kg

Installation

The M19 is employed in tactical and nuisance minefields.

The M 19 is buried or surface-laid.

The M19 requires a force of 157 to 225 kilograms to detonate.

Standard FDs may be used with the M2 activator in any of the
secondary fuse wells of the M 19.

WARNING
Emplace and remove the mine while in the
prone position.

Inspect the mine.

— Do not usethemineif it is dented, cracked, or damaged.

— Remove the M606 fuse from the fuse well by turning it
counterclockwise a quarter turn (Figure A-27).

— Ensure that the rubber gasket is on the M 606 fuse.

M606 fuse

Pressure plate ~-~L

Safety-clip cord
Fuse well

Activator well

Setting knob

Shipping plug

\
/Detonator ^

well

t)etonator-holde^r-^- |J j[j]
assembly y\> " y "

Bottom of
pressure plate

Figure A-27. Removal of the pressure plate

A-22 Installation and Removal of US Mines and Firing Devices

FM 20-32

— Remove any foreign material from the fuse well.

— Ensure that the setting knob is in the SAFE position and that the
safety clip is in place.

— Use the M22 wrench to remove the shipping plug from the
detonator well.

— I nspect the detonator well for foreign material. If foreign material
is present, gently tap the pressure plate with your hand to
dislodge the material.

Test the position of the firing pin (Figure A-28).

tv>>

JiS&§M^

±+ .s^ij^'vy

Armed

Safe

Figure A-28. Firing pin

— Ensure that the firing pin is at the edge of the well when the
setting knob is in the SAFE position.

— Remove the safety clip.

— Use the M22 wrench to turn the setting knob to the ARMED
position. Ensure that the firing pin is in the center of the well.

— Use the M22 wrench to turn the setting knob back to the SAFE
position. Ensure that the firing pin moves back to the side of the
well. NOTE: If the firing pin is not in the correct position
when the setting knob is in the ARMED or SAFE position,
notify the NCOIC.

— Replace the safety clip.

Use the M22 wrench to screw the M50 detonator into the detonator
well.

Use the M22 wrench to tighten the M 606 fuse into the fuse well.

Dig a holetofit the mine.

— Dig a hole deep enough sothat thetopof the pressure plate will be
even with or slightly below ground level.

Installation and Removal of US Mines and Firing Devices A-23

FM 20-32

Removal

M21

— Dig the sides of the hole at a 45-degree angle to prevent vehicles
from bridging the mine.

Empl ace the mine.

— Place the mine in the hole.

— Cover the mine with soil until it is level with the top of the
pressure plate.

Arm the mine.

— Remove the safety clip.

— Use the M22 wrench to turn the setting knob from the SAFE
position totheARMED position.

Camouflage the mine.

— Cover the mine with 3 centimeters of soil.

— Camouflage the mine, place excess soil in sandbags, and remove
sandbags from the area.

— Givethe safety clip and theshipping plug to the NCOIC.

Disarm the mine.

— Clear the soil from thetop of the mine carefully.

— Hold the mine firmly in place with one hand, without putting
pressure on the pressure plate.

— Feel for AHDs with the other hand by digging around the sides of
and underneath the mine.

— Use the M22 wrench to turn the setting knob to the SAFE
position.

— Replace the safety clip on the M 606 fuse.
Remove the mine.

— Remove the mine from the hole.

— Use the M22 wrench to remove the M606 fuse by turning it
counterclockwise and lifting it out of the fuse well.

— Use the M 22 wrench to remove the detonator from the detonator
well.

— Replace theshipping plug in thedetonator well.

— Replace the pressure plate in the mine.

The M21 AT mine (Figure A-29) utilizes a direct-energy warhead that is
designed to produce a K-K ill. It is used in conjunction with the M 607 fuse. The
M 21 produces a K-Kill against heavy tanks, unless the mine is activated
under the track. It can be buried with a tilt rod, or it can be surface-laid with

A-24 Installation and Removal of US Mines and Firing Devices

FM 20-32

or without a tilt rod. If the M21 is surface-laid with a tilt rod, it must be
staked to prevent it from being knocked over and causing the warhead to be
directed away from the target. The M21 is not compatible with any
mechanical mine-dispensing system.

M607 fuse

Shipping plug

Concave
steel plate

Black-powder
expelling charge

M42 primer

-230 mrrr

charge

Carrying
strap Delay

element

M120 booster

Closing plug

Figure A-29. M21 AT mine

Characteristics

Main Charge

Diameter

Height

Weight

No Mines per Box

Weight per Box

Comp H6, 4.95 kg

230 mm

115 mm

7.8 kg

4

41 kg

• The M21 requires a minimum of 130.5 kilograms of pressure to
detonate.

• The M 21 can be used with a tilt-rod assembly, requiring 1.7 kilograms
of pressure on the extension rod to cause a 20-degree deflection.

• The M21 is the only conventional US AT mine with a direct-energy
warhead.

Installation and Removal of US Mines and Firing Devices A-25

FM 20-32

Installation

WARNING
Emplace and remove the mine while in the
prone position.

Inspect the mine.

— Do not usethemineif it is dented, cracked, or damaged.

— Ensurethat thecotter pins on the fuse pull-ring assembly and the
fuse-closure assembly are securely in place (Figure A-30).

— Inspect the fuse to ensure that the neck portion behind the tile
collar is not cracked.

Extension-rod adaptor

\ Extension rod

Closure
assembly

J) V/j^^Pressure ring
\ ^ Band

VL

Fork

Pull-ring
assembly

Figure A-30. M607 fuse

I nsert the booster.

— Use the screwdriver end of the M26 wrench (Figure A-31) to
remove the closing plug from the bottom of the mine.

Closure-assembly end

Screwdriver
end

Shipping-plug end

Figure A-31. M26 wrench

A-26 Installation and Removal of US Mines and Firing Devices

FM 20-32

— Inspect the booster well for foreign material. If foreign material is
present, gently tap the top of the mine with your hand to dislodge
the material. If you cannot remove the debris, replace the closing
plug and do not use the mine.

— Insert the M120 booster (with the washer side toward the fuse)
i nto the booster wel I .

— Replace the closing plug with the M26 wrench.
Fuse the mine.

— Remove the shipping plug from the fuse well with the M26
wrench.

— Inspect the fuse well for foreign material. If foreign material is
present, gently shake the mine to dislodge the material. If black
powder falls out of the fuse well or you cannot remove the foreign
material, do not use the mine.

— Remove the closure assembly from the M607 fuse with the M26
wrench. Ensure that the gasket remains in pi ace on the fuse.

— Screw the fuse hand-tight into the fuse wel I.
Dig a holetofit the mine.

— Dig a hole deep enough so that the top of the mine will be at
ground level (Figure A-32).

Figure A-32. Buried M21 mine

— Check the bottom of the hole to ensure that the ground is solid
enough to support the mine. If necessary, place a flat object under
the mine to provide a firm foundation. Allow additional depth for
the object.

Empl ace the mine.

— Place the mine in the hole.

— Cover the mine with soil until it is level with the top of the mine.
Ensure that no soil falls around or under the plastic collar.

Installation and Removal of US Mines and Firing Devices A-27

FM 20-32

— Press the soil firmly around the sides of the mine.

• Assemble the extension rod. NOTE: For pressure operation, do
not use the extension -rod assembly.

— Screw the extension rod onto the M 607 fuse.

— Ensure that the extension rod is pointing straight up.

• Arm the mine.

— Squeeze the end of the cotter pin together on the pull ring.

— Remove the cotter pin by holding the fuse firmly in one hand and
pulling the pull ring with theother hand.

— Remove the band and the stop slowly and carefully from the neck
of the fuse (F igure A-33).

Cotter pin

Pull-ring assem
Stop

Figure A-33. Removing the band and the stop

Camouflage the mine.

— Camouflage the mine with twigs, grass, or other material in the
area. Place mines with extension rods in tall grass, if possible.
Ensurethat no pressure is applied tothetilt rod or thefuse.

— PI ace the excess soil in sandbags and remove them from the area.

A-28 Installation and Removal of US Mines and Firing Devices

C2, FM 20-32

Removal

Give the band, the stop, the pull ring, the shipping plugs, and the
closure assembly to the NCOI C.

Disarm the mine.

— Clear the camouflage away from the mine carefully.

— Attach the band and the stop to the fuse.

— Insert the cotter pin into the band and the stop. Spread the ends of
the cotter pin.

— Remove the extension rod.
Check for AH Ds.

— Hold the mine firmly in place with one hand, without putting
pressure on the fuse.

— Feel for AHDs with the other hand by digging around the sides of
and underneath the mine.

Remove the mine.

— Remove the mine from the hole.

— Remove the fuse from the mi ne.

— Install the closure assembly on the fuse.

— Install the shipping plug into the fuse well of the mine.

— Remove the closing plug from the bottom of the mine.

— Remove the booster from the mi ne.

— I nstall the closing plug into the booster well.

Section III. Firing Devices and Activators

An FD performs the fundi on of a mine fuse by providing an alternative means
to detonate the mine. It is normally used in conjunction with a standard fuse
so that a mine will have two separate explosive chains. The purpose of the
second firing chain is to prevent the enemy from disarming or removing mines
after emplacement. When used for this purpose, the FD is called an AHD and
it is designed to fundi on by detonating the attached mine or another explosive
charge nearby if unauthorized personnel attempt to remove or tamper with
the mine. NOTE: US forces will not employ AHDs on AP mines. Both the
M19 and the M15 have two secondary fuse wells for attaching an FD and an
adivator.

There are two standard US F Ds— M 5 pressure release and M 142
multipurpose. They utilize a spring-loaded striker and a standard base and
aredesigned tofundion in one or more of the foil owing modes:

Installation and Removal of US Mines and Firing Devices A-29

C2, FM 20-32

• Pressure.

• Pressure release.

• Tension.

• Tension release.

M5 PRESSURE-RELEASE FIRING DEVICE (MOUSETRAP)

The M5 FD (Figure A-34) is activated by the release of pressure. Lifting or
removing a restraining weight releases the striker to fire the cap.

Interceptor or

improvised positive

safety-pin hole

Locking
safety pin

Locking
safety pin

Standard

Protective cap-
always remove)

Activator

Gasket

e§§3- Cap

Standard base

M5 pressure-
~~ release FD

Interceptor pin
(thin wire)

Pressure base

Characteristics

Figure A-34. M5 FD

Case: Metal.

Color: Olive-drab.

Length: 445 millimeters.

Width: 239 millimeters.

Height: 175 millimeters.

Internal action: Mechanical with hinged striker release.

Initiating action: Removal of restraining weight, 2.25 kilograms or
more.

Accessories: Pressure board.

Safeties: Safety pin and holefor interceptor pin.

Packaging: Four complete FDs and four plywood pressure boards are
packaged in a paper carton, five cartons are packaged in a fiberboard
box, and 10 fiberboard boxes are shipped in a wooden box.

A-30 Installation and Removal of US Mines and Firing Devices

Installation

FM 20-32

Dig a hole deep enough to bury the mine on a firm foundation. The
pressure plate should be slightly above ground level.

WARNING
Ensure that the mine and the FD are resting on
a firm foundation before removing the pins.

Remove the protective cap from the standard base. Assemble the FD.

Use a coat hanger as a positive safety pin. Place the mine in the hole.
Leave enough room to remove the pins.

Bury and camouflage the mine.

Arm the mine.

Remove the locking safety pin (Figure A-35).

Removal

XS

Positive safety
interceptor hole (remove last)

Locking safety pin
(remove first)

Figure A-35. Arming the M15

Remove the positive safety pin (interceptor pin). NOTE: If the
positive safety pin is difficult to remove or if you hear a click
when removing the locking safety pin, carefully remove the
mine and replace the FD.

Uncover the mine carefully and inspect it for tampering. Locate and
carefully uncover theFD.

WARNING
DO NOT release the pressure being applied
to the device.

I nsert the positive safety pin into the interceptor hole, and then insert
the locking safety pin into the safety-pin hole.

Installation and Removal of US Mines and Firing Devices A-31

FM 20-32

• Disarm and removethe mine. Recover the FD.

M142 MULTIPURPOSE FIRING DEVICE

The M 142 FD (Figure A-36) can be designed to function in the following
modes:

• Pressure (11 kilograms or more).

• Pressure release (between 2 and 67 kilograms).

• Tension (3 kilograms or more).

• Tension release.

/ FIRING OtVltt *
Of MO MUU\
PURPOSE M \<U ^

(or no me-80 jooi - oov

Spool or trip wire

Fastening devices

Tension-release
device

Shipping
container

Explosive

coupler ^t^ 1 ^"^

M Positive safety

(remove last)

Square-head
safety pin

Figure A-36. M1 42 FD

Although primarily intended for booby-trap applications, the M 142 can be
readily adapted as an AHD. The M142 comes with a coupling device and a
primer that accepts a standard nonelectric blasting cap. The initiating action
sets off an explosive chain that passes from the FD and the primer to the
blasting cap, and then via the detonating cord to the main charge. However,
the coupling device with the primer will not initiatethe detonating cord alone

A-32 Installation and Removal of US Mines and Firing Devices

CI, FM 20-32

without a blasting cap attached, and it is not adaptable to any activator or
secondary fuse well. When the M 142 is used as an AHD, the coupling device is
removed and an M 1 or M 2 standard base is used.

Characteristics

• Case: Plastic.

• Color: Olive-drab.

• Diameter: 190.5 millimeters.

• Length: 571.5 millimeters.

• Internal action: Spring-driver striker.

• Safeties: Positive safety pin, square-head pivot pin, round-head pivot
pin, and alternative safety-pin hole.

• Accessories: Nail and screw fasteners, coupling assembly, tension-
release attachment, 15-meter spool of trip wire, and vinyl instruction
sheet.

• Packaging: Round, metal can containing FD with accessories.

Arming and Disarming

Arming and disarming procedures vary based on the activation mode.
Detailed instructions are printed on a weatherproof, vinyl sheet included in
each FD package.

Ml AND M 2 ACTIVATORS

When FDs are employed with M15 and M19 AT mines, they requiretheuseof
an M 1 or M 2 activator.

Activators are essentially detonator boosters that are designed to magnify the
explosive force generated by an FD with a standard base and transfer the
force to the main charge. Activators may be used with either type of FD to
supply an AT mine with a secondary fuse for antihandling purposes. The Ml
activator is used with the M 15 AT mine, and the M 2 activator is used with the
M 19 AT mine. The activator also performs the function of an adapter for
attaching the FD to the mine. One end of the activator is threaded externally
for insertion in the secondary well of the mine; the other end is threaded
internally to receive the standard base coupling of the FD.

The Ml activator (Figure A-37, pageA-34) is 54 millimeters long (with cap), is
made of olive-drab plastic, contains a detonator, and has a threaded closing
plug and a gasket. It has a cylindrical, unthreaded cap that is cemented to the
opposite end of the body and contains a tetryl booster charge. The threaded
end, which screws intothe mine, is 25 millimeters in diameter.

TheM2 activator is similar to the Ml except that it contains an HE pellet, and
its overall length, with cap, is 53 millimeters.

Installation and Removal of US Mines and Firing Devices A-33

FM 20-32

Tetryl cup

Well for standard base

Figure A-37. M1 activator

A-34 Installation and Removal of US Mines and Firing Devices

C2

Appendix B

Controls and Components of
Special-Purpose Munitions

This appendix provides characteristics and detailed descriptions of US
special-purpose munitions. The use of these munitions is outlined in
Chapter 4.

SELECTABLE LIGHTWEIGHT ATTACK MUNITION

The SLAM is a multipurpose munition with antidisturbance and antitamper
features. There are two models of the SLAM— one is self-neutralizing (M2)
and the other is self-destructing (M4). The M2 is solid green and has no labels,
brands, or other distinguishing marks. The M4 is green with a black warhead
(EFP)face.

Employment methods for the SLAM are outlined in Chapter 4.

Figure B-l describes and illustrates the major components of the SLAM.

Component

Description

Mounting holes (1)

The mounting holes are used to secure the carrying strap or the mounting wire to the
SLAM when attaching the SLAM to trees and so forth.

Bore sights (2)

Two bore sights and an omega sight are located on the top of the SLAM and are used to
aim the SLAM at targets.

Selector switch (3)

The selector switch is used to select operating modes and times. It has eight detent
positions. The switch is against a stop (in the shipping position), which is the only switch
position that allows the SLAM to fit in the reusable environmental protective pack.
Turning clockwise, there are three positions for selecting the operating time (4, 10, and
24 hours). Setting any of these positions will select an internal sensor mode of
operation, which is a magnetic sensor for mine mode and a passive infrared sensor for
side-attack mode. These three positions will cause the SLAM to self-destruct (M4) or
self-neutralize (M2) at the end of the selected operating time. Continuing clockwise, the
last four positions select an internal timer, which sets the minutes until demolition. These
positions are 15, 30, 45, and 60 minutes.

Activation-lever
shear pin (4)

There is a shear pin mounted across the SLAM's lever slot. If the shear pin is sheared,
thereby breaking the seal, the lever may have been pulled and the SLAM may be an
electronic dud. If the shear pin is broken, it should only be used in the command-
detonation mode.

Safety pin (7)

The safety pin slides from the body and starts the SLAM's timing. It is pried from its latch
with the tip of the lever. Once the safety pin is pulled, it cannot be reinserted.

Figure B-1. SLAM components

Controls and Components of Special-Purpose Munitions B-1

C2, FM 20-32

Component

Description

Passive infrared
sensor (8) and
cover (9)

The SLAM is equipped with a passive infrared sensor that detects trucks and light
armored vehicles by sensing the change in background temperature as vehicles cross in
front of the SLAM. The sensor is directional and is aligned with the EFP. The sensor is
active when the SLAM is operating with the selector switch set to 4, 10, or 24 hours and
the sensor cover is removed to expose the infrared sensor (such as, during the side-
attack mode). The SLAM will self-destruct (M4) or self-neutralize (M2) if the selected
time expires before it is detonated by vehicle passage.

Blasting-cap well
and plug (10)

The threaded plug seals the blasting-cap well
blasting cap with a priming adapter.

It is removed to mount a standard military

Warhead (11)

The warhead is an EFP that is designed to defeat light armored vehicles. The EFP forms
within the first 5 inches of flight and has an effective range of 25 feet.

Housing assembly
(12)

The housing assembly contains the fusing, electronics, and S&A components. It also
provides a structural interface for the warhead, the sights, the activation lever, the
passive infrared sensor, the selector switch, and the safety pin.

Figure B-1. SLAM components (continued)

M93 HORNET

The M93 Hornet is a lightweight (35 pounds) AT/antivehicular munition that
one person can carry and employ. It is a one-time use, nonrecoverable
munition that is capable of destroying vehicles using sound and motion as
detection methods. The Hornet will automatically search, detect, recognize,
and engage moving targets, using top attack at a maximum standoff distance
of 100 meters. It is employed by units equipped with an M71 RCU. The RCU is
a hand-held encoding unit that interfaces with the Hornet when the remote
mode is selected at the time of employment. After encoding, the RCU can be
used to arm the Hornet, reset SD times, and destruct the Hornet.
Employment methods of the Hornet are outlined in Chapter 4.

Figure B-2 describes and illustrates the major components of the Hornet.
Figure B-3, page B-4, describes and illustrates the controls and indicators of
the Hornet.

B-2 Controls and Components of Special-Purpose Munitions

C2, FM 20-32

Component

Description

Support legs (1)

Support legs are used to stabilize the Hornet when it is deployed.

Active battery-
pack cover (2)

The active battery-pack cover provides a seal to protect and secure the active battery
pack. The latch is lifted up to remove the cover, the active battery pack is installed, and
the cover is then reinstalled and latched down. A line secures the battery-pack cover to
the control panel of the munition.

SD switch (3)

The SD switch is a six-position rotary switch that is used to select the SD time and
unlock the arm control switch. The SD switch is also used to unlock the arming lever.
This is done by rotating the switch to the setting "U." A red lock element is extended 1/8
inch from the side of the munition when the SD switch is in the unlock position. The SD
time is preset to Setting 1 when the Hornet is shipped. SD times are as follows:

Settina Time

1 4 hours

2 48 hours

3 5 days

4 15 days

5 30 days

Arm control
switch (4)

The arm control switch consists of an arming lever interlocked with the SD switch and
the S&H band assembly to prevent inadvertent actuation. Until the S&H band assembly
is removed and the SD switch is placed in the unlock position, the arming lever cannot
be moved to the arm position. An internal lock secures the arming lever in the arm
position.

Microphones (5)

When the geophone seismic sensor detects a potential target, usually at ranges up to
600 meters, it alerts the munition to start listening with the three microphones that
extend from the munition body. They track the two loudest noise sources that are heard.

Antenna (6)

The antenna provides a means for the Hornet to receive M71 RCU commands.

Capture screws
(7)

These are four flat-head screws that secure the bottom plate to the munition body. They
are removed along with the bottom plate to access the battery compartment.

Bottom plate (8)

The bottom plate provides a seal to protect and secure the battery compartment and
connect the batteries once they are installed.

D-cell batteries
0)

The battery compartment houses four D-cell batteries. A drawing on the inside of each
battery tube shows battery orientation.

Dowel pin (10)

The dowel pin ensures that the bottom plate is in the correct orientation to properly
connect the batteries.

Figure B-2. Hornet components

Controls and Components of Special-Purpose Munitions B-3

C2, FM 20-32

Figure B-2. Hornet components (continued)

Component

Description

Magnetic
coupling device
(MCD)(1)

This device is used as part of the RCU interface. The RCU interface consists of the
MCD and keyed tabs. In the remote arming mode, the RCU is placed on top of the MCD
and minefield code data is transferred to the munition. Upon successful encoding, the
status light begins to flash.

Target switch (2)

The target switch is a toggle switch used to select the type of target engagement. This
gives the operator the choice between detecting and destroying only heavy armored
vehicles or all vehicles.

Manual select
switch (3)

The manual select switch is a push-button switch, protected by a plastic cover that must
be removed to access the switch. Successful activation of the switch will cause the
status light to flash. This switch is used to allow the operator to employ the Hornet
without the RCU.

Status light (4)

The status light is a visual indicator for the operator during the munition setup. It is a
green light-emitting diode (LED) that indicates a self-test was successfully performed or
an operating-mode selection was successfully selected.

SD switch (5)

See Figure B-2, page B-3.

Arming lever (6)

See Figure B-2.

Active battery-
pack cover (7)

See Figure B-2.

Figure B-3. Hornet controls and indicators

B-4 Controls and Components of Special-Purpose Munitions

C2, FM 20-32

2

1

<&£^fr $ 3^

4
5

I! &

in

U^

-~ 7j 7

3

Figure B-3. Hornet controls and indicators (continued)

Controls and Components of Special-Purpose Munitions B-5

C2

Appendix C

Threat Mine/Countermine Operations

This appendix is intended to complement the information presented in
other manuals on threat obstacle tactics. It applies to most threat armies
and their surrogates. Commanders should use this information to give
added realism to unclassified training, although obstacle employment
norms can change with METT-TC factors for a given AO. Therefore,
preoperational training on templating, intelligence, reconnaissance, and
reduction procedures must be based on the best information available
before deployment.

Appendix G contains a compilation of countermine data.

MINE OPERATIONS

Threat formations contain considerable organic minefield emplacement
capability. Threat rapid-mining capability presents a serious challenge to
friendly maneuver.

To lay mines and place obstacles rapidly during offensive operations, threat
armies form a special team from regimental and divisional assets. This team
is called a mobile obstacle detach merit (MOD). The MOD places AT mines on
the most likely avenues for armored attacks or counterattacks. MODs are
positioned on the flanks of a march formation for rapid deployment and are
normally close to AT reserves. During the march, MODs reconnoiter avenues
into the flanks and identify the most likely avenues for tank movement. At
secured objectives, MODs reinforce existing obstacles and place new obstacles
to assist in the defeat of counterattacks.

The combined arms commander orders the organization of MODs and
determines their composition based on the combat situation and available
troops. E ngineer elements in a division M OD come from the divisional
engineer battalion and normally consist of three armored tracked minelayers
known as GMZs (F igure C-l, page C-2). This platoon-sized element has two or
three trucks that carry mines for immediate resupply. For the regimental
MOD, the regimental engineer company normally provides a platoon-sized
unit equipped with two or threeGMZs. The platoon travels in BTR-50/60s and
has 600 AT mines.

The GMZ dispenses mines at a predetermined spacing of 5.5 meters. M ine-
laying helicopters also support the MOD. The HIP andHIND-D helicopters
carry two or three dispenser pods of AP or AT mines. Artillery-fired
SCATMINEscan also support the MOD. ThreeGMZs can lay a 1,200-meter,
three-row minefield, containing 624 mines, in 26 minutes. Doctrinally, this
minefield would be broken into several minefields, each 200 to 300 meters
long.

Threat armies use obstacles extensively throughout the depth of their defense,
and their tactics are chosen well. Shallow obstacles are reduced quickly and
easily. For example, a shallow, one-row minefield is essentially reduced by
blowing one or two mines in the row. A threat rapidly emplaced minefield

Threat Mine/Countermine Operations C-1

FM 20-32

Figure C-1. GMZ armored tracked mine layer

consists of three or four 200- to 300-meter rows, spaced 20 to 40 meters apart,
with mines spaced 4 to 6 meters apart. As a rule, the minefield covers the
depth of a football field.

Table C-1 provides detailed information on standard threat AT and AP
minefields. Terrain and tactical situations dictate the actual dimensions and
distances of minefields.

Table C-1. Normal parameters for threat-style minefields

AT Minefields

Front (situation-dependent)

200 to 300 meters

Depth

40 to 1 20 meters

Number of rows

3 or 4

Distance between rows

20 to 40 meters

Distance between mines

4 to 6 meters for antitrack mines; 9 to 12 meters for
anithull mines

Outlay, normal

550 to 750 antitrack mines per kilometer; 300 to 400
antihull mines per kilometer

Outlay, increased effect

1 ,000+ antitrack mines per kilometer; 500+ antihull
mines per kilometer

Probability of destruction

57% for antitrack mines (750 per kilometer); 85% for
antihull mines (400 per kilometer)

AP Minefields

Front (situation-dependent)

30 to 300 meters

Depth

1 to 1 50 meters

Number of rows

3 or 4

Distance between rows

5+ meters for blast mines; 25 to 50 meters for
fragmentation mines

Distance between mines

1 meter for blast mines; 50 meters (or twice the lethal
radius of fragmentation) for fragmentation mines

Outlay, normal

2,000 to 3,000 HE/blast mines per kilometer; 1 00 to 300
fragmentation mines per kilometer

Outlay, increased effect

2 to 3 times the normal outlay

Probability of destruction

15 to 20% for HE/blast mines (2,000 per kilometer); 10
to 15% for fragmentation mines (100 per kilometer)

C-2 Threat Mine/Countermine Operations

FM 20-32

Figure C-2 shows a standard rapidly emplaced minefield. The threat army
typically uses such a minefield when they are in a hasty defense (offense is
temporarily stalled).

Figures C-3 shows a standard antitrack minefield.

Figure C-2. Threat-style rapidly emplaced minefield

\~+ 200-300 m

T # <

20-40 m

• ••••••

r* — *i
4-6 m

Figure C-3. Threat-style antitrack minefield

40-80 m

Threat Mine/Countermine Operations C-3

FM 20-32

FigureC-4 shows a standard antihull minefield.
Figure C-5 shows a standard AP minefield.

200-300 m

H

20-40 m

70-80 m

9-12 m

Figure C-4. Threat-style antihull minefield

30-300 m

*¥VVV¥VVV

¥t V ¥ V V ¥ ¥ V 10-150 m
5+ m T

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1

Blast Mines

Types: PMN, MPMD-GM
Density: 2,000-3,000 per kilometer

*T *

25 m

30-300 m

¥ V

i¥

V

25-50 m

¥

¥ 10

150 m

Fragmentation Mines

Types: OZM4, POMZ-2M
Density: 100-300 per kilometer

Figure C-5. Threat-style AP minefield

C-4 Threat Mine/Countermine Operations

FM 20-32

Threat armies also emplace mixed minefields. They are not the same as US
mixed minefields. Threat armies normally emplace three rows of AT mines,
then several rows of AP mines. AT and AP mines are not mixed in the same
row.

Threat engineers use two fundamental drills toemplace mines:

• When emplacing armed mines, the drill uses a crew of five sappers.
The first crew member (the senior man and operator) is in the mine-
layer's seat and monitors the operation of the mine layer and the
motion of the mines in the guide chute. He also sets the mine spacing
and controls the actions of theGMZ. The second and third members
take mines out of containers and place them in the intake chute at
intervals between the guide tray's drive chain. TheGMZ driver steers
the vehicle along the indicated route at the established speed.

• When emplacing unarmed mines, two or three additional sappers are
assigned to arm the mines. After emplacing the mines, one sapper
trails the mine layer, marks emplaced mines with pennants, and
partially camouflages the mines. The remaining sapper(s) then arm
the mines.

Special precautions are taken when emplacing AP minefields. Threat doctrine
only allows PMN mines to be surface-laid from mine layers. POM Z-2M mines
are emplaced with the truck-and-tray technique. Extra effort is required to
assemble, emplace, and deploy the trip wire and to camouflage the POMZ-2M
mine.

UsingthreeGMZs, a threat MOD can emplace 1,200 meters of a three-row AT,
surface-laid minefield, containing 624 AT mines, in 26 minutes. This does not
include the 12- to 15-minute reload and travel times. Travel and reload times
increase during limited visibility.

Threat forces can also have ground-emplaced SCATMINE capability. One such
system is the U M Z SCATM I N E system (F igure C-6, page C-6). There are
three UMZ truck-mounted SCATMINE systems in each combat regiment. The
UMZ consists of six firing modules mounted on the back of a Zi 1-131 truck.
Each module has 30 firing tubes, for a total of 180 firing tubes per system.
Depending on the type of minefield desired, the UMZ can lay 180 to 11,520
mines without reloading. The UMZ can launch an AT or AP minefield 30 to 60
meters from the vehicle while the truck is driving 10 to 40 kph. It takes two
men V-h to 2 hours to reload the UMZ. One UMZ can lay a three-row
minefield, 150 to 1,500 meters long, depending on the type of mine that is
used.

UMZ vehicles are usually deployed together as a mobile obstacle/mine-laying
detachment. The UMZ is used to lay minefields that protect subunit positions
and flanks and the boundaries between subunits. UMZ-laid minefields also
cover firing lines and gaps in combat formations. The UMZ can quickly close
gaps in existing minefields and increase the density of mines on armor
avenues of approach.

For hand-emplaced SCATM I NEs, there is a man-portable SCATM I NE
dispenser. The PKM weighs 2.63 kilograms (without the mine canister) and
consists of a single launch tube with a base mount, a blasting machine, and a
reel of electric ignition wire. The operator loads a propelling charge and a
mine canister into the launch tube and mounts the tube on the edge of a
trench or firing parapet. He then aims the tube, connects the ignition wire to

Threat Mine/Countermine Operations C-5

FM 20-32

Figure C-6. UMZ SCATMINE system

the tube, and moves to a safe distance. At an initiating point, the operator
connects the ignition wire to the blasting machine and initiates the system.
The PKM propels the canister 30 to 100 meters, depending on the type of
mine. It lays an AP minefield that is 10 by 20 meters (POM-IS mine canister),
10 by 40 meters (POM-2S mine canister), or 20 by 10 meters (PFM-1S mine
canister). It takes a trained operator 5 minutes to set up the PKM and create a
minefield. The PKM can also be used to launch thePTM-lS and PTM-3 AT
mine canisters.

Threat forces use the PKM to lay minefields that protect subunit positions
and flanks and the boundaries between subunits. PKM-laid minefields also
cover firing lines and gaps in combat formations. The PKM can quickly close
breaches in existing minefields and increase the density of mines on armor
avenues of approach.

The type and complexity of an obstacle depends on the installing unit.
Maneuver and artillery soldiers usually install simple single-system
minefields that are protective in nature. Engineer soldiers install complex
obstacles that can include AH Ds. E ngineer obstacle placement is usually
equipment-intensive. Threat engineer effort generally concentrates on tactical
obstacles unless maneuver soldiers are unable to employ the necessary
protective obstacles. Threat units continue to improve the obstacles,
supporting their positions by marking the friendly side of the obstacles,
burying mines, and adding AH Ds.

CHEMICAL MINES

Chemical land mines are AP mines with command- or target-detonated fuses,
and they are filled with a persistent chemical (nerve or blister) agent. US
policy prohibits their use by US personnel. However, this does not preclude
their use by other countries, and US forces may encounter them during
operations. When used, they are normally used in defense and retrograde
operations. They are mixed with HE mines to form a HE chemical minefield.
Chemical mines are normally encountered in tactical or nuisance minefields,
and some countries use them in protective minefields. When an integrated HE
chemical minefield is laid, it serves the following purposes:

• Chemical mines discourage the use of explosive, rapid mine-clearing
devices because they create a chemical hazard in the area.

C-6 Threat Mine/Countermine Operations

FM 20-32

• HE mines reduce the speed of enemy forces crossing the minefield.
Speed is further reduced by forcing the enemy to use protective
clothing and masks.

Chemical mines will usually be added to existing HE minefields by laying
additional strips of chemical mines in a random pattern or by adding HE
chemical strips or rows to the front or rear of existing fields (Figure C-7).

Chemical mines

Figure C-7. Chemical-mine employment

No particular branch is responsible for clearing chemical mines. Planning
chemical countermine operations is a brigade-level responsibility. When
reducing chemical mines, consider prevailing and expected wind conditions.
Commanders must ensure that friendly troops are protected when chemical
agents are released. The release of chemical agents occurs as a result of
enemy fire or friendly breaching attempts. Contact-actuated chemical mines
are not likely to create a major downwind hazard because only single mines or
small groups may beset off at onetime.

COUNTERMINE OPERATIONS

Organization

I n offensive operations, threat engineers clear lanes through obstacles when
they cannot be bypassed. Although clearing obstacles applies to the march and
the defense, the most critical performance of this task occurs during the
attack. Engineers can be required to clear mines delivered by air, artillery, and
rockets well ahead of NATO's forward edge. They must breach obstacles
contained within NATO strongpoints. Threat forces must also clear their own
minefields when making the transition from defense to offense. In the offense,
threat forces breach or bypass remotely delivered minefields in their form-up
areas or routes of movement to the attack line. They also breach obstacles
along the forward edge of the battle area and deep within NATO defenses.

Although clearing passages through obstacles is a primary task for threat
engineers, any maneuver element may encounter mines. Engineers may not
be ableto respond to every encounter, so maneuver troops are also required to
breach through remotely emplaced obstacles.

A movement support detachment (MSD) supports the movement of maneuver
forces. It is task-organized from divisional or regimental engineer assets and

Threat Mine/Countermine Operations C-7

FM 20-32

can be platoon- to company-size. The MSD is equipped with route- and mine-
clearing vehicles and devices. Depending on the mission (which comes directly
from the combined arms commander or the chief of engineer services), an
M SD is capable of filling craters, clearing minefields, preparing bypasses
around major obstructions, and identifying NBC-contaminated areas.

The divisional engineer battalion can form two or three MSDs. During
marches, MSDs travel in advance of the main body and clear obstructions
reported by division reconnaissance elements. When they are deployed on
main routes, they are under the protection of an advance guard or forward
security element. When deployed on other routes, the leading regiments
provide MSDs from organic engineer assets. An MSD at this level might
consist of an engineer platoon, with one or two dozers and up to three tanks
fitted with dozer blades. MSDs can be protected by a platoon of infantry or
tanks and are usually accompanied by chemical -reconnaissance personnel.
They can detect, mark, and breach hasty minefields that are not properly
covered by fire. If MSDs encounter properly defended minefields, their
clearing capabilities are limited.

Each battalion forms an obstacle-clearing group to create gaps in explosive
and nonexplosive obstacles. Normally a part of a battalion-level MSD, the
group follows first-echelon companies in APCs and creates gaps for those
forces. These units may possess BAT-M vehicles with BTU bulldozer blades
(FigureC-8) or KMT-series mine plows (FigureC-9).

Figure C-8. BAT-M with BTU bulldozer blade

CZZ3=

Figure C-9. KMT-4 plow

C-8 Threat Mine/Countermine Operations

FM 20-32

An obstacle-clearing detachment is created when more resources are needed
to clear obstacles and debris. This usually occurs in urban environments and
under conditions of massive destruction. An obstacle-clearing detachment is
similar to an MSD, but its sole mission is to clear debris. Like an MSD, its
composition depends on the mission scope, the mission objective, and the
tempo of the offensive.

The divisional engineer battalion of the motorized rifle or tank division has a
sapper company to clear obstacles. The company commander receives a
mission to clear minefields. He then determines the exact location of the
obstacle, ascertains the assets to devote to the task, and plans the
methodology for success. Teams may be created to manually breach lanes
using probes, IMP portable mine detectors (Figure C-10), and shovels. Larger
tasks may necessitate the use of vehicle-mounted DIM mine detectors (Figure
C-ll), armored vehicle mine plows and/or rollers (Figure C-12, page C-10),
and explosive line charges. When necessary or more practical, mines are
explosively destroyed in place.

Figure C-10. IMP portable mine detector

Figure C-11. DIM mine detector

Threat Mine/Countermine Operations C-9

FM 20-32

Figure C-12. KMT-5 plow-roller combination

The engineer company of the motorized rifle or tank regiment has breaching
equipment such as KMT-series mine plows and rollers and BTU bulldozer
blades located in its technical platoon. Because of limited assets in the
technical platoon, coupled with the responsibility of forming its own MSD, the
regiment can receive a sapper section from the divisional sapper company. An
additional I MR armored engineer tractor (Figure C-13), BTR-50/60, and
M1979 armored mine clearer (Figure C-14) and manual breaching equipment
come with the sapper section.

Figure C-13. IMR armored engineer tractor

Maneuver units usually breach remotely emplaced obstacles by using
attached, built-in breaching equipment (BTUs and KMTs). In order to carry
out this task successfully, all subunit commanders must organize constant
reconnaissance, notify subordinates about mined areas in a timely manner,
train personnel on the means and methods for handling remotely emplaced
mines, and clear terrain in a timely manner. They must also train their own
teams for independent actions when removing combat equipment from mined
areas. Plows in the threat army areconsidered maneuver-force assets, and one
plow is assigned to each tank platoon. The BMP has recently been equipped
with track-width mine plows, but the allocation has not been determined.

C-10 Threat Mine/Countermine Operations

FM 20-32

Figure C-14. M1979 armored mine clearer

Equipment

BAT-M Dozer

Several pieces of equipment are used by threat armies to detect and clear
mines.

The BAT-M dozer (FigureC-8, pageC-8) is a modified artillery tractor with a
hydraulically operated bulldozer blade and crane. It is sometimes called a
roader by Russians. The BAT-M dozer clears obstacles, fills craters, prepares
bridge approaches, and performs other heavy pioneer tasks. It can also be
configured for snowpl owing.

The second generation BAT-M istheBAT-2. TheBAT-2 is able to carry an 8-man
engineer squad and operatein an NBC environment. It is replacing the BAT-M.

KMT-Series Plows and Rollers

KMT-4

KMT-5

The KMT-4 mine-clearing plow (Figure C-9, page C-8) was developed in the
1960s to fit on a T-545/55 tank. It actually consists of two plows (one mounted
in front of each track), and each plow has five attached teeth. When the plow
is lowered, the teeth dig into the ground and remove mines from the path of
the tank. A plow is lighter than a roller and permits tanks to retain their
cross-country mobility. The estimated clearing speed is 10 kph, and the depth
of clearance is 10 centimeters.

Three plows are issued per tank company (one per platoon). However, these
assets are normally held in the engineer company of a tank or MRR.

The KMT-5 mine-clearing plow-roller combination (Figure C-12, page C-10)
consists of two plows and two rollers attached to the front of a tank hull. The
plows or the rollers can be used, depending on terrain features, the type of
soil, and the mine fuse. Plows and rollers cannot be used simultaneously. The
rollers function against pressure-fused mines. The system can survive 5 to 6
kilograms of explosives, five or six times. The KMT-5 also includes a luminous
lane-marking device for night operations.

Threat Mine/Countermine Operations C-11

FM 20-32

KMT-6

KMT-10

The KMT-6 mine-clearing plow was introduced with theT-64 and T-72 tanks
in the early 1970s. It has operating characteristics similar to those of the
KMT-4.

The KMT-10 mine-clearing plow is fitted to the BM P-2 infantry combat
vehicle.

I MP Portable Mine Detector

The I MP portable mine detector (Figure C-10, pageC-9) weighs 7 kilograms
and can detect mines buried to a depth of 45 centimeters. It has a tubular
search head (one transmitting and two receiving coils encased in plastic) and a
four-section handle. Power is furnished by four flashlight batteries that
permit 20 hours of continuous operation. Two tuning controls are mounted on
the handle. The coils in the search head compromise an induction bridge and
are initially balanced for zero coupling. When the head passes over a metallic
object, the induction bridge becomes unbalanced and produces an audible
signal in the headset.

DIM Vehicle-Mounted Mine Detector

The Dl M vehicle-mounted mine detector (Figure C-ll, page C-9) is primarily
used to clear roads during convoys and road marches. It sweeps at a speed of
10 kph with a 2.2-meter width. It can detect metallic mines at a depth of 25
centimeters. The brakes on the Dl M automatically engage when a mine is
detected. Cross-country use of the DIM is limited.

I MR Armored Engineer Tractor

The IMR armored engineer tractor (Figure C-13, page C-10) is mounted on a
modified T-54/55 chassis. The turret is removed and a hydraulic crane, which
can be fitted with either a grab or an excavator bucket, is emplaced. An
adjustable, hydraulically operated blade is mounted on the front. The crane
operator is provided with an armored cupola. The I MR can operate in an NBC
environment.

M 1979 Armored Mine Clearer

The M1979 armored mine clearer (Figure C-14, page C-ll) is mounted on the
chassis of an amphibious 122-millimeter, 2S1 self-propelled howitzer. It has a
turret-likesuperstructurethat contains three rockets on launch ramps. These,
along with the upper part of the superstructure, are hydraulically elevated for
firing. The rocket range is estimated at 200 to 400 meters. Each rocket is
connected to 170 meters of mine-clearing hose via a towing line. The hose is
folded and stowed in the uncovered base of the turret and connected to the
vehicle with a cable. The cable allows the vehicle crew to reposition the hose
after launching.

C-12 Threat Mine/Countermine Operations

This chapter implements STANAG 2990.

Appendix D

Air Volcano

The air Volcano system provides a three-dimensional capability that
allows units to emplace minefields in deep, close, and rear operations. It
provides US forces with the capability to employ minefields rapidly under
varied conditions. The air Volcano can be used to emplace tactical
minefields; reinforce existing obstacles; close lanes, gaps, and defiles;
protect flanks; and deny the enemy use of potential air-defense sites.
Volcano minefields are ideal for flank protection of advancing forces and
for operating in concert with air and ground cavalry units on flank-guard
or screen missions.

COMPONENTS

The air Volcano system (Figure D-l) consists of an M87-series mine canister,
an M 139 dispenser, and vehicle-specific mounting hardware (UH-60
Blackhawks require a jettison kit).

Figure D-1. Air Volcano system

M87-Series Mine Canister

The M 87-series mine canister is the same canister used for the ground
Volcano system:

• M87. Prepackaged with fiveAT mines, one AP mine, and a propulsion
device inside a tube housing.

• M87A1. Prepackaged with six AT mines and a propulsion device
inside a tube housing.

The mixture of mines is fixed and cannot be altered in thefield. The mines in
each canister are electrically connected with a web that functions as a lateral

Air Volcano D-1

FM 20-32

dispersion device as the mines exit the canister. Spring fingers mounted on
each mine prevent the mine from coming to rest on its edge. AT mines have a
delay-arm time of 2 minutes 30 seconds; AP mines have a delay-arm time of 4
minutes. All canisters are capable of dispensing mines with 4-hour, 48-hour, or
15-day SD times. SD times are selected prior to dispensing and do not require
a change or modification in the base M87-series mine canister.

M139 Dispenser

The M 139 dispenser consists of an electronic DCU and four launcher racks;
each rack holds 40 M 87-series mine canisters. The racks provide the
structural strength and the mechanical support required for launch and
provide the electrical interface between the mine canisters and the DCU.
Mounting hardware for the UH-60A Blackhawk includes a jettison
subassembly to propel the Volcano racks and canisters away from the aircraft
in the event of an emergency.

The operator uses the DCU to electrically control the dispensing operation
from within the aircraft. The DCU provides controls for the arming sequence
and the delivery speed selection, and it sets mine SD times. The DCU allows
the operator to start and stop mine dispensing at anytime. A counter on the
DCU indicates the number of canisters remaining on each side of the aircraft.

Mines are dispensed from their canisters by an explosive propelling charge, 35
to 70 meters from the aircraft's line of flight. The aircraft flies at a minimum
altitude of 1.5 meters, at speeds of 20 to 120 knots. It can deliver up to 960
mines per sortie.

LIMITATIONS

The total weight of the air Volcano system is 2,886 kilograms. An aircraft will
be close to its maximum gross weight when it contains the Volcano system and
a full crew. Based on weather and environmental conditions, the aircraft may
be required to execute the mission without a full fuel load, thus reducing
en route time.

The flight crew cannot operate the M60D machine gun with the air Volcano
system installed, and it takes 3 to 4 hours to install the air Volcano system on
a UH-60A Blackhawk.

EMPLOYMENT

The air Volcano is the fastest method for emplacing large tactical minefields.
When employed by combat aviation elements in support of maneuver units,
close coordination between aviation and ground units ensures that mines are
emplaced accurately and quickly. Although placement is not as precise as it is
with ground systems, air Volcano minefields can be placed accurately enough
to avoid the dangers inherent in minefields emplaced by artillery or jet
aircraft.

Air Volcano minefields can be emplaced in friendly and enemy territories.
They should not be planned in areas of enemy observation and fire, because
the helicopter is extremely vulnerable while flying at the steady altitude, the
speed, and the path required toemplacethe minefield. The air Volcano is the

D-2 Air Volcano

FM 20-32

best form of a situational obstacle because of its short emplacement time. Its
employment varies dependi ng on the type of operation.

Deep Operations
E mployment

The air Volcano is employed in deep operations to—

• Disrupt enemy formations along key AAs and choke poi nts.

• Fix enemy formations in EAs to enhance target acquisition by attack
helicopters, CAS, artillery, or a combination of weapon platforms.

• Provide area denial of possi ble enemy artillery and ADA sites that will
affect future friendly schemes of maneuver.

AH-64 security is essential to air Volcano missions because the target area
must not be in the enemy formation's direct line of sight. It may require two
suppression of enemy air defense (SEAD) missions to get the air Volcano
across the F LOT to the target location. This removes the security aircraft from
the battle. All air Volcano missions require planning, designation, and control
during the execution of air corridors (routes).

Aviation Configuration

The air Volcano can be used in deep operations, but it has distinct limitations.
The aircraft can maintain a speed of 80 to 90 knots (UH-60A) for 90 to 120
kilometers, depending on the wind and the temperature (see Table D-l, page
D-4).

The aircraft cannot employ the door guns for self-defense with the Volcano
system mounted. The attack aircraft averages 100 to 120 knots while
targeting enemy formations that are 150 to 200 kilometers deep. I n order for
the air Volcano to go deep, the attack aircraft must slow down or special
security/escort aircraft must be assigned for protection. The security/escort
can be AH-64s or OH-58D Kiowa Warriors (KWs). KWs have many
advantages— they are not a primary killing platform, and they are very good
at quickly securing an area. The air Volcano requires one or two security
aircraft for protection, and there should also be a backup aircraft for the
mission.

Fire-Support Coordination

The division main (light force) or brigade main (mechanized force) FSE is
responsible for coordinating and executing fires in support of air Volcano
missions. Upon completion of the target meeting, the FSE, the assistant
division/brigade engineer, and theG3/S3 air representative will coordinate to
ensure that the air-coordination/tasking order will support the mission and
the planned SEAD fires.

If the mission is a deep aviation attack, the aviation element FSE is
responsible for coordinating through the forward command post to the
division/brigade main FSE. If the forward command post hasjumped forward
or has not deployed, the aviation element FSE will coordinate directly with
the division/brigade main FSE.

Air Volcano D-3

FM 20-32

Table D-1. Air

volcano capabilities and limitations

Pressure
Altitude (ft)

Temperature
(°C)

Maximum
Weight (lb) 1

Cruise

Speed

(knots/kph)

Fuel Burn

Rate
(lb per hr)

Endurance
(hr + min) 2

Maximum

Range
(nm/km) 3

Planning
Combat
Radius

(nm/km) 4

+20

22,000

80/148

965

1 +57

1 54/285

60/111

90/166

1,040

1 +48

1 60/296

1 00/1 82

1,145

1 +35

1 58/292

+30

22,000

80/148

975

1 +56

1 56/289

59/109

90/166

1,045

1 +48

1 60/296

1 00/1 82

1,160

1 +34

1 56/289

+40

21,600

80/148

995

1 +53

1 50/277

58/107

90/166

1,055

1 +45

1 56/289

100/182 7

1,175

1 +33

1 54/285

2,000

+20

22,000

80/148

960

1 +58

1 57/290

60/111

90/166

1,060

1 +45

1 57/290

1 00/1 82

1,155

1 +35

1 58/292

+30

21 ,000 5

80/148

1,000

1 +28

117/217

45/83

90/166

1,045

1 +23

124/229

100/182 7

1,175

1 + 12

120/222

+40

20,000 6

80/148

1,005

1 +21

28/52

7/13

90/1 66 7

1,075

1 + 19

29/53

100/182 7

1,150

1 + 16

27/49

NOTE: Based on UH-60A with an aircraft torque factor of 97.5.

1 Maximum weight for deep operations only; no interdiction capability.

2 Endurance includes 20-minute fuel reserve.

3 Does not compensate for winds. This is the maximum range line-of-site distance.

4 The general planning figures used for time-on-target missions; includes compensation for 1 0-knot winds,

makeup for lost time, and a 5-minute on-station time.

5 1 ,800 pounds of fuel at takeoff

6 700 pounds of fuel at takeoff

7 Operation at this air speed may be limited to 30 minutes due to target limits.

LIMITATIONS:

• There are no modifications to mount the M60D machine gun on the air Volcano aircraft.
Crews cannot use the M60D with the system mounted on an aircraft.

• Crews cannot fly the aircraft with full tanks above +30°C and 2,000-ft pressure altitude.

• Aircraft may require a rolling takeoff and landing, depending on ambient weather conditions.

Close Operations

E mployment

The air Volcano is employed in close operations to fix enemy formations in
EAs, turn advancing formations into desirable terrain that supports the
friendly scheme of maneuver, disrupt formations enough to slow the enemy
down, and block key AAs. Multiple missions may be required, depending on

D-4 Air Volcano

C2, FM 20-32

the intended effect. The air Volcano can be used to reseed existing minefields
or to close lanes and gaps. The target area must be clear of friendly forces
before an air Volcano mission is executed.

Use of the air Volcano in close operations should be a primary planning
consideration. It can quickly reach the outer edge of the forward operating
base where AAs need a minefield obstacle. The threat level will be lower, and
the station time will increase.

Aviation Configuration

Two air Volcano aircraft should be used (one primary, one backup). The
requirement for security aircraft depends on METT-TC factors, but security
should be used whenever possible.

Fire-Support Coordination

The forward command post FSE coordinates and executes fires in support of
air Volcano missions. The FSE, the engineer liaison officer, and the G3/S3
representative coordinate to ensure that the air coordination/tasking order
supports the mission and the planned SE AD fires. The division/brigade main
will be avail able to support the forward command post as necessary.

The brigade/TF FSE is responsible for coordinating through the forward
command post to the division/brigade main FSE. If the forward command post
has jumped, the brigade/TF FSE coordinates directly with the division/brigade
main FSE.

Rear Operations
E mployment

The primary purposes of the air Volcano in rear areas is to protect key terrain
from possible airborne/air-assault forces and to fix/disrupt enemy forces long
enough to allow the tactical combat force or ready-reserve force time to react
and meet the changing enemy situation.

The least preferred employment method is to deliver tactical minefields to
brigade and corps support areas. This employment tactic is normally used
when all other available assets have been exhausted. The flexibility of the air
Volcano system makes it ideal for employment against a mounted Level III
threat in the rear. The target area should be out of the direct view/fire of the
threat and on a choke point that allows cover for the reacting forces.

Aviation Configuration

The air Volcano aircraft could be employed individually or with security/escort
aircraft. The use of OH-58D KWs as security aircraft allows units to develop
the situation and helps place minefields in the proper location to assist
inbound attack aircraft or fires. If the air Volcano aircraft is not provided
security aircraft, it is recommended that ground forces provide covering fires.

Fire-Support Coordination

The division/brigade rear FSE coordinates and executes fires in support of air
Volcano missions. The FSE, the engineer liaison officer, and the G3/S3
representative coordinate to ensure that the air coordination/tasking order

Air Volcano D-5

FM 20-32

supports the mission and the planned SEAD fires. The division/brigade main
will be availableto support the division/brigade rear as necessary.

The headquarters element that controls the rear area coordinates with the
division/brigade rear FSE. The division/brigade rear FSE coordinates with the
division/brigade FSE for fire support and air assets.

Minefield Effects

Turn

A turn minefield manipulates enemy maneuver in a desired direction. It
forces or entices enemy formations to move in a different direction rather than
breach the obstacle. This means the bypass must be easily identified. Turn
minefields are extremely lethal, with approximately 80 percent probability of
mine encounter. The typical width is 557 by 320 meters for air Volcano. Figure
D-2 shows two turn minefields combined tocreatea turn-effect obstacle group.
It takes 160 canisters (800 AT/160 AP mines) to empl ace one turn minefield.
One air Volcano aircraft can lay oneturn minefield (see Table D-2).

Aircraft line of flight

320 m

(1) (2)

557 m

557 m

NOTE: Numbers correspond to the aircraft pass.

320 m

(3) (4)

Figure D-2. Turn obstacle
Table D-2. Air Volcano minefield data

Type of
Minefield

Depth (m)

Frontage of
Minefield (m)

Number
of Strips

Canisters per
Strip

Total
Canisters

Minefields per
Aircraft

Disrupt

120

278

1

40
(20 each side)

40

4

Fix

120

278

1

40
(20 each side)

40

4

Turn

320

557

1

80

(40 each side)

160

1

Block

320

557

1

80

(40 each side)

160

1

Block

A block minefield (Figure D-3) is designed to stop an enemy advance along a
specific AA or allow it to advance at an extremely high cost. Block minefields
are obstacles with intensive integrated fires. They should be employed in a

D-6 Air Volcano

Disrupt

FM 20-32

complex obstacle scheme with road craters or bridge demolitions enhancing
the effectiveness of the minefield. One air Volcano aircraft can lay a 557- by
320-meter block minefield, using all 160 canisters (800 AT/160 AP mines). The
probability of mine encounter is more than 80 percent. One Volcano aircraft
can lay one block minefield, making two passes side by side (see Table D-2).

i
Aircraft line of flight

1 320 m

■ ■ Ml
557m , , , ,

y y y y

0) (2)

Figure D-3. Block obstacle

A disrupt minefield (Figure D-4) fractures and breaks up enemy formations. It
causes premature commitment of reduction assets, interrupts C 2 , and alters
timing. A disrupt minefield is not resource- or time-intensive. The probability
of mine encounter is approximately 50 percent, and thetypical width is 278 by
120 meters. It takes 40 canisters (200 AT/40 AP mines) to emplace one disrupt
minefield. One air Volcano aircraft can lay four disrupt minefields (see Table
D-2).

Fix

Figure D-4. Disrupt obstacle

A fix minefield (Figure D-5) slows enemy formations within a specified EA. It
gives friendly forces time to acquire, target, and destroy enemy formations. A

Air Volcano D-7

FM 20-32

fix minefield is employed in depth and causes enemy formations to react and
breach repeatedly. The air Volcano fix minefield does not look impenetrable to
enemy formations. The probability of mine encounter is 50 percent, and the
typical size is 278 by 120 meters. It takes 40 canisters (200 AT/40 AP mines)
to emplace one fix minefield. One air Volcano aircraft can lay four fix
minefields (see Table D-2, pageD-6).

i

I

120 m

•

m

(4)

Aircraft line of flight

278 m

WO) A

U

J m m\

•

(3)\ ►

278 m

•

(2)

A

u

120 m

Linear

Figure D-5. Fix obstacle

If the threat situation allows, the aircrew makes a pass to confirm the
minefield end points and the suitability of the terrain. I n a high-threat
situation, the aircrew emplaces the minefield on the first pass. This hasty
minefield is linear in configuration and is 1,115 by 75 meters. All 160
canisters are fired.

Planning

Responsibilities
Division Commander

The division commander approves air Volcano employment and integration
into deep, close, and rear operations. He is also the authority for SCATMINE
employment.

Maneuver Brigade Commander

When authority is delegated by the division commander, the maneuver
brigade commander is responsible for employing air Volcano in close
operations and in supporting follow-on missions. He is responsible for
approving target nominations to be submitted to the division. The maneuver
brigade commander receives the air Volcano aircraft and its crew in OPCON
status.

D-8 Air Volcano

FM 20-32

Aviation Brigade Commander

The aviation brigade commander is responsible for integrating the air Volcano
into deep aviation attacks and for shaping EAs in the division AO. He
executes the air Volcano missions in deep, close, and rear operations. The
aviation brigade commander submits target nominations to the division
targeting cell through the aviation brigade engineer and provides support for
transporting and loading Volcano mines.

Division Engineer

The division engineer is responsible for target nominations that support
division missions or objectives in deep operations. He—

• Submits the nominations tothedivision targeting cell.

• Determines minefield characteristics.

• I ncorporates the Volcano minefield, DTG of SD times, and safety zones
intothedivision obstacle plan.

• Estimates the requirements for mine canisters and Class IVA/
supplies.

• Determines the intent of the Volcano minefield as it is integrated into
the division obstacle plan.

• Disseminates the SCATM IN WARN to adjacent and subordinate units
before the minefield is laid and one hour before theSD sequence of the
minefield is initiated.

Brigade Engineer

The brigade engineer is responsible for target nominations that support
objectives within his respective fight. He—

• Submits target nominations to the assistant division engineer.

• Synchronizes air Volcano missions into brigade operations.

• Assists the brigade FSE in planning SE AD, CAS, and Apache escort.

• Provides logistics estimates to the brigade S4 for coordination of
ammunition requirements.

• Posts the operations map with the minefield's location, aviation
graphics, the safety zone, and the DTG of SD times.

• Disseminates the SCATM IN WARN to adjacent and subordinate units
before the minefield is laid and one hour before SD sequence of the
minefield is initiated.

Deputy Fire-Support Coordinator

The deputy FSCOORD recommends commanding general/chief of staff
approval for target nominations developed by the division targeting cell. He is
responsible for submitting division-approved air Volcano target nominations
totheG3 air for inclusion in the air coordination order. Hecoordinates SEAD,
CAS, and intelligence and electronic warfare for division-directed air Volcano
missions. The deputy FSCOORD is also responsible for—

Air Volcano D-9

FM 20-32

G3Air

Targeting (intelligence and asset coordination).
The air tasking order.
TheG3 air coordination order.
G2 collection and assessment.

The G3 air synchronizes coordination and deconfliction of division air space
for air missions, SEAD, and CAS. When necessary, he submits the air
coordination order to higher headquarters with the division-approved target
list.

Emplacing Unit/UH-60 Company

Process

The emplacing unit or the designated UH-60 company sets up and loads the
air Volcano system in conjunction with the forward-area refuel point. The
Volcano system is loaded on the UH-60 at the designated point. The emplacing
unit/UH -60 company is also responsible for—

• Maintaining the unit basic load at the forward-area refuel point or
ATP.

• Preparing the scatterable minefield report and record, forwarding it to
the authorizing commander or the aviation brigade engineer, and
verifying that the assistant division/brigade engineer receives the
entire report.

Coordinating air routes and corridors.

Requesting SEAD and security aircraft.

Planning the air-mission coordination meeting to refine or develop the
aviation scheme of maneuver.

Ensuring that pilots attend the unit's rehearsal.

Posting aviation graphics on the current operations overlay.

All target nominations are submitted through the division targeting cell. In
the brigade, all target nominations go to the assistant division engineer for
submission to the board. Nominations should be submitted 96 hours prior to
the execution time (see Table D-3).

• The targeting cell validates the targets based on the SITE MP and
recommends approval through the commanding general/chief of staff.

• U pon approval, the deputy FSCOORD turns the target numbers and
the air requirements over to the G3 air, who adds the targets to the air
coordination order.

• The deputy FSCOORD begins to plan SEAD/CAS requirements for
division missions.

• The G3 issues the division WO so that units can be prepared to
execute specific air Volcano missions.

D-10 Air Volcano

FM 20-32

Table D-3. Planning process (H-hour sequence)

H-96+00. Submit target nominations/receive approval. Submit CAS requests for enemy ADA sites along
ingress and egress routes.

H-72+00. Receive mission. Division WO issued.
Conduct air-mission coordination meeting.

• Conduct S2 update on enemy situation and pass down to executing unit.

• Submit additions or changes to the CAS request to FSE for enemy ADA sites.
Post the air Volcano mission in the air coordination order.

• Disseminate the SCATMINWARN.

H-48+00. Mount the system. The system takes 3 to 4 hours with a crew of three on a hard surface. The
time is doubled in a field environment and requires three or four personnel to assist in loading.

H-24+00. Conduct detailed mission analysis and planning. Issue WO to attack assets, including —
NLT time for mission planning and upload completion.
Time and location of air-mission brief.
Units attending.
Minefield location and type.
Establishment of C 2 relationship.
Face-to-face coordination with attack assets.
Liaison officers planning multiple routes to minefield.

Liaison officers coordinating with engineers, ADA, and FSEs for support. G4/S4 must be notified of
reload plans and any other Class lll/V requirements.
Intelligence update.

H-20+00. Volcano integrated into deep attack or air-assault matrix by the aviation brigade.

H-8+00. Conditions-check matrix approved by the commanding general or designated authority,
including —

• Weather.

• Threat suppression along route.

• Attack support.

FLOT crossing coordination completion.
FLOT initial crossing point.
SEAD fire coordination.

• Mines available.

Integration into execution matrix.

• Crews updated on ADA threat.

• Backup system and aircraft available.

• CAS coordination.

Rehearsal completion with attack assets.
Intelligence update.

• Close operation mission, including —

— Location of friendly forces.

— Type of marking and when it will be in place.

H-6+00. Conduct air-mission brief, including —

• S2 intelligence update.

• ADA threat update.
Rehearsal held after brief.

• Brigade engineer and brigade fire-support officer being present.

H-4+00. Latest time for link-up of aviation assets. Fly to forward-area refuel point or tactical assembly area
for mine load-up. Remember that —

• Loading canisters takes 1 to 3 hours with a crew of four to eight. Time varies greatly based on
whether or not the canisters are in shipping containers.

• The loading time in a field environment is decreased if one pad is dedicated to air Volcano aircraft
loading and arming.

H-0+30. Cross FLOT (estimated; exact time is based on route), to include —

• SEAD fired.

• CAS sorties.

H-hour. Minefield deployed, to include —

• Aircraft reports to the supporting brigade engineer if an infantry brigade mission.

• Aircraft reports to the aviation brigade engineer if a division mission.

• Engineer disseminates the scatterable minefield report and record to appropriate units.

Air Volcano D-11

FM 20-32

Logistics

The division issues a fragmentary order (FRAGO) to order the
execution of the air Volcano mission.

The planning staff gives the aviation brigade a date and a time for the
air Volcano system to be uploaded and prepared for employment.

Air Volcano minefields are integrated into the scheme of maneuver as
a directed, situational, or reserve obstacle as stated in FM 90-7. This
includes integration into the COA that is synchronized during war
gaming and included in theOPORD as part of the rehearsal.

Air Volcano munitions are transported and handled in the same manner as
Class V mines and explosives. The only significant difference in handling is
whether air Volcano operations are conducted from thetactical assembly area
or the forward operating base.

Echelon-above-corps transportation assets will transfer the air Volcano to
corps storage areas (ammunition). Based on forecasts by the division
ammunition officer, the corps support area will push air Volcanos to ASPs or
ATPs in the division area (tactical assembly area). ASPs and ATPs in or near
the tactical assembly area are normally operated by a direct-support
ammunition company attached to the corps support group (forward). ATPs in
brigade support areas are normally operated by forward support battalions.
Mines are moved from the corps support area to ASPs/ATPs by transportation
units from the corps support group (rear). Further throughput of mines from
ASPs to ATPs is supported by transportation assets from the corps support
group (forward). Based on the division ammunition officer's forecast and the
availability of transportation, the corps support area will attempt to transfer
bulk mines to the ASP/ATP that is best positioned to support requirements.
ATPs issue mines to using units while ASPs handle bulk ammunition. ASPs
can do emergency issue to using units, but this is usually done only for units
using large quantities of bulk ammunition and having their own ammunition
transportation support available (division or corps artillery).

Preparation and Coordination

If an air Volcano mission has been approved for a unit, an aviation brigade
liaison officer coordinates with the S3 air, the engineer, and the air defense
officer to outline air Volcano requirements.

Logistical Requirements

The engineer planner calculates Class WIN supplies and requests them from
the Assistant Chief of Staff, G4 (Logistics)(G4)/S4. The engineer and the
assistant division aviation officer coordinate the location (forward-area refuel
point, tactical assembly area, forward operating base) of the ATP where the
UH-60 will be loaded and fueled. The ALO must provide the amount of air
time available and the fuel required, and he must be prepared to discuss
emplacement times based on Volcano locations. The air-mission brief will
facilitate dissemination of this information.

D-12 Air Volcano

FM 20-32

Concept of the Operation

The scheme of maneuver, fires, and engineer operation must be outlined. The
scheme of engineer operations outlines exact grid coordinates, the obstacle
intent, and the minefield composition and size. The air Volcano can be
emplaced under enemy contact, but additional control measures must be used
to protect the aircraft and the crew. If the air Volcano is triggered by enemy
action, the DST must be briefed during the air-mission brief. The DST must
outline NAIs, including the type of sensors and triggers (long-range
surveillance device [LRSD], SOF, UAV), TAIs, decision points, and execution
criteria.

Control Points and Markers

The initial point, the approach marker, and minefield markers are designated.
Approach and minefield markers must be visible from the air and be distinctly
different from one another:

• The initial point is an easily identifiable terrain feature used for
coordi nati ng the entry poi nt of the U H -60 i nto the sector.

• The approach marker allows the aircraft to set the altitude, the speed,
and the final orientation to the minefield. The approach marker can
also be a terrain feature.

• Minefield markers establish the limits of the desired minefield. Deep
area minefields do not require minefield markers.

Terrain Analysis

A combined (aviation, maneuver, fire-support, and engineer planners) terrain
analysis should be conducted using Terrabase or a similar product. Terrabase
enables planners to analyze the effects of the terrain in a three-dimensional
format. AAs, terrain references, TAIs, NAIs, line-of-sight profiles, and
minefield locations can be confirmed during this analysis.

Air-Mission Brief

The air-mission brief is the most critical planning and coordination meeting at
the execution level, and it must occur no later than H-6 in the planning
process. During the air-mission brief—

• C 2 is established.

• Updates and changes to the situation are exchanged between the
brigade or TF engineer, the fire-support officer, and the air-mission
commander.

• The engineer and the air-mission commander use four control
techniques (discussed later in this appendix) to ensure mission
success. The primary technique for emplacement and the
responsibilities for each control technique are outlined.

• Radio frequencies; points of contact; codewords; identification, friend
or foe, modes; and challenge and passwords are exchanged and
disseminated.

Air Volcano D-13

FM 20-32

Mounting

Execution
Siting

Movement

The forward-area refuel point location, the security aircraft, flight
routes, and lethal/nonlethal SEAD are identified (if already approved).

The system must be mounted no later than H-48 in the planning process.

The key to proper emplacement is the location of the minefield in relation to
existing terrain features. If appropriate, the minefield should tie into an
existing terrain feature to prevent easy bypass or fording. Using Terrabase
enhances siting and emplacement procedures in deep operations.
Reconnaissance must be conducted to verify the location.

Loading. The launcher rack functions as the carrier and launcher platform
for 40 mine canisters. The rack has 40 keyholes for mine canisters, a green
latch that latches the mine canister to the rack, and a red latch that arms the
mine canisters. The rack has two electrical receptacles— one for the connector
and one for the launcher rack cable from the DCU. While looking at the
canister side of the rack, rows are 1 through 4 from bottom to top and columns
are 1 through 10 from left to right.

Arming.

Due to the weight of the Volcano mine system, a large, open area that
is clear of obstacles must be selected. The site should have a hard
surface if possible. If a hard surface is unavailable, inspect the ground
to ensure that it is firm enough to support the weight of the aircraft.
Perforated steel planking or two pieces of 1-inch plywood (4 by 4 feet)
may be used as a field-expedient surface in soft areas.

Concentrations of nonessential personnel or frequently traveled
vehicular routes should not be within 1,000 meters of the site. This
distance is based on the total weight of explosives and the safe
fragmentation distance found in FM 5-250. When using the M88
training canisters, the minimum distance is 30 meters.

Two Underwriters Laboratories, Incorporated (UL)-listed 10BC fire
extinguishers and a grounding rod (minimum safety equipment) must
be available at the arming point. This equipment is provided by
personnel who deliver the mines.

The number of personnel allowed access to the site should be held to a
minimum. All personnel involved in the arming will receive a safety
brief that includes—

— Ammunition handling and inspection procedures.

— Loading procedures.

— E mergency procedures and rendezvous points.
Emergency procedures.

D-14 Air Volcano

FM 20-32

— Fire. In the event of a fire away from the mines, attempt to contain
or extinguish the fire by any available means. If the fire is near
the mines or in them, clear the area to a minimum distance of
1,000 meters and notify fire-fighting personnel immediately. When
training with M 88 canisters, clear the area to a minimum distance
of 30 meters.

— Accidental discharge. I mmediately clear the area to a distance of
640 meters and notify EOD. The mines arm approximately 2%
minutes after firing. When training with M 88 canisters, terminate
arming until the problem can be identified and corrected.

— Failure to fire. Remove the canister from the aircraft and place it
in the dud pit. Notify EOD immediately. When training with M88
canisters, remove the canister from the aircraft, separate it from
the other canisters, repack it, and return it to the ASP.

Site layout (Figure D-6).

Dud pit

I

Ammunition
points

o

i_

c
o

O

o

Spent ammunition

o

Figure D-6. Site layout

— Berming of the site is not required for a tactical arming point.

— The following rules apply when the site is located next to a refuel
point:

> A minimum of 1,000 meters must exist between arming points
and refuel points when the total quantity of explosives is less
than 600 kilograms. For quantities greater than 600
kilograms, refer to FM 5-250.

NOTE: Each M87 canister contains 3.4 kilograms of explosives; a full
load (160 canisters) contains 550 kilograms of explosives.

Air Volcano D-15

C2, FM 20-32

> The refuel point for armed aircraft must be located at least
375 meters from other aircraft refueling points.

> Parked, armed aircraft must be at least 36 meters from other
armed aircraft to prevent the detonation of explosives on
adjacent aircraft. This distance will not prevent damage to
adjacent aircraft; a 130-meter distance is required to prevent
damage by fragments and to ensure that the aircraft remains
operational.

— A dud pit (bermed when possible) for damaged or misfired
ammunition should be established beyond the ammunition points.

— Arming points should be laid out as shown in Figure D-6.

Dearming. After the mission is complete, the aircraft returns to the arming
point for dearming. Spent canisters should be discarded at least 30 meters
from the aircraft, at the 4- and 8-o'clock positions. Live canisters should be
returned to ASPs for future use or repackaging. Canisters that misfire should
be placed in the dud pit.

Flight Planning and Preflight.

• The flight crew analyzes the mission using METT-TC factors and
determines the flight profile to be used during mine emplacement. It
will select (or have designated) one or more of the following control
measures to be used during mine emplacement:

— Visual identification (start and stop markers on the ground).

— Time-lapse (tables to determine the minefield length).

— Number of canisters fired.

— Doppler/GPS (start and stop coordinates).

• The crew member(s) will ensure that the air Volcano is installed
properly, that all installation checks are completed, and that mine
canister pallets are loaded as directed by the pilot or the SOP.

• The flight crew conducts ground checks according to the checklist in
TM 1-1520-237-10 to confirm proper operation of the air Volcano prior
to takeoff.

Before Arrival at the Target Area.

• During the equipment check, the crew chief turns on the DCU power-
control switch, verifies that no malfunctions were indicated during the
initial built-in test, and turns off the DCU power-control switch.

• After completion of run-up with the aircraft at flight idle, the crew
chief turns on the DCU power-control switch.

• Before arrival at the release point, the pilot will make the following
checks (listed on the Volcano card [a sample is shown in Figure D-7]):

— Verify that the DCU is on.

— Verify that the mine SD time is properly set.

D-16 Air Volcano

FM 20-32

VOLCANO CARD

Emplacement Date:

Unit

Engr

ASP

A

Call Sign

Frequency

Location

N

Remarks

Not to scale

1 st pass

2nd pass

3rd pass

4th pass

Initial Point

A

D

G

J

SD Time

Ground Speed

knots
kph

knots
kph

knots
kph

knots
kph

No Tubes

Altitude

Track

Start Time

B

E

H

K

Stop Time

C

F

I

L

Figure D-7. Sample Volcano card

Announce the ground speed in knots or kph, as required. (The
pilot and the crew chief will acknowledge.)

Announce the number of canisters the crew chief will count down.
If deployment is 40 canisters per run (20 per side) and there are
two runs, the crew chief will count down from 80 to 60 on the first
run and 60 to 40 on the second run. (The crew chief will
acknowledge.)

Announce the
acknowledge.)

altitude for employment. (The pilot will

Announce the course for the delivery track. (The pilot will
acknowledge.)

Air Volcano D-17

FM 20-32

— Announce the delivery time based on the setting of the ground
speed. (The crew chief will acknowledge.)

• Before arrival at the initial point, the crew chief will—

— Ensure that the DCU fire-circuit switch's safety pin and streamer
are removed.

— Ensurethat the DCU fire-circuit switch is enabled.

— Place the interface control-panel arming switch to the ARM
position. He will verify that the jettison advisory light indicates
armed and that no fault codes are displayed on the DCU.

At the Target Area.

• The pilot simultaneously announces "mark," presses the go-around
switch, and starts timing the run when he is over the minefield start
point.

• The pilot maintains a ground speed of 5 kph/3 knots and an altitude of
3 meters during the mine-dispensing pass. The pilot is responsible for
flying the aircraft within the prescribed limitations.

• The crew chief announces the mine-canister count, as the canisters
aredispensed, by counting down in 10s. Hethen announces the last
three canisters. For example, the pilot announces a canister count of
60, the crew chief calls out "80, 70, 3, 2, 1, mark."

• The pilot terminates mine dispensing when the grid location is
reached.

After Mission Completion.

The crew chief will—

• Place the interface control -panel arming switch to the SAFE position
and verify that the armed advisory capsule is extinguished.

• Place the DCU fire-circuit switch to the OFF position. Install the
safety pin and the streamer.

Prepare and submit a SCATMINWARN.

EMPLACEMENT

The air Volcano is fast and flexible, but it is difficult to accurately dispense
mines within the confines of the minefield marking. The desired obstacle-
effect norms for the air Volcano require extensive planning, preparation,
coordination, and positive control during emplacement. The critical aspect of
the air Volcano is getting the right amount of mines in the specified location
and in the desired density.

The detailed coordination focuses on positive control. Positive control of an air
Volcano mission requires a redundancy of control techniques to minimize
errors in minefield size and location. These control techniques must
compensate for poor visibility, wind speed and direction, and navigational
errors.

D-18 Air Volcano

FM 20-32

The following control techniques are used by the engineer and the air-mission
commander to ensure that Volcano minefields match specific obstacle-effect
norms. Units rely on these techniques to accomplish the mission, and they are
part of the Volcano air-mission brief:

• Visual identification. Focuses on the visual identification of minefield
emplacement. As part of the preparation for a Volcano minefield, an
engineer element erects airfield panel markers to mark start and end
points. This provides a visual signal for the engineer and the air-
mission commander to start and stop firing Volcano canisters. The
pilot depresses the launch switch over the first marker to start firing
and depresses it again over the second marker to stop firing. This
control technique is good for open terrain with adequate visibility and
little canopy coverage.

• Time lapse. Focuses on when to stop firing Volcano canisters. The UH-
60's air speed and the type of minefield being laid determines the
amount of time it takes to lay a minefield. The air Volcano has six air
speed settings— 20, 30, 40, 55, 80, and 120 knots. Table D-4 shows the
time required to lay minefields and the full load time.

Table D-4. Air Volcano dispensing times based on air speed

Knots

Disrupt and Fix
Minefields

Turn and Block
Minefields

160 Canisters
per Load

20

27 seconds

54 seconds

108 seconds

30

18 seconds

36 seconds

72 seconds

40 1

13 seconds

27 seconds

54 seconds

55

9 seconds 2

18 seconds

39 seconds

80

6 seconds 2

13 seconds 2

27 seconds

120

4 seconds 2

9 seconds 2

18 seconds

Width of minefield (meters)

278.8

557.5

1,115

No passes per minefield

1

2 3

1

No canisters per pass

40

80

160

1 Recommended air speed

2 Recommended only if absolutely necessary

3 Blackhawks in pairs can lay turn and block minefields in one pass, firing 80 canisters each.

The following example is provided to show how Table D-4 is used:

Example: The mission is to install an air Volcano disrupt minefield.
The UH-60 is traveling at 40 knots (this is entered on the DCU), and
the pilot initiates (depresses the launch switch) at the identification of
the Volcano start marker or the grid location on the ground. The pilot
depresses the launch switch a second time after 13 seconds have
elapsed.

Number of canisters fired. Focuses on when to stop firing Volcano
canisters. The number of Volcano canisters dispensed also determines
when firing is terminated. There is a digital readout on the DCU (for

Air Volcano D-19

FM 20-32

the left and right side) that shows the number of canisters remaining.
The pilot stops firing when the required number of canisters have
been fired (see Table D-4, page D-19).

Using the disrupt minefield example above, the U H-60 starts the
mission with a full load (80 canisters on each side of the aircraft). The
pilot initiates (depresses the launch switch) at the identification of the
Volcano start marker or the grid location on the ground. The pilot
depresses the launch switch a second time after 20 canisters have
been expended on each side. The DCU counts down from the total
number of canisters. When the DCU reads 60 right/60 left, the pilot
depresses the switch to end the firing process. Ideally, the timing of
delivery and the number of canisters fired are done simultaneously. As
the crew chief counts down the timer, the pilot and the crew chief
monitor the number of canisters remaining on the DCU digital
readout.

Doppler/GPS. Focuses on when to start and stop firing Volcano
canisters using the UH-60's Doppler/GPS guidance and navigation
set. This set provides the present position or destination in latitude
and longitude (degrees and minutes) or grid coordinates. As part of the
preparation for the Volcano minefield, exact grid coordinates are
needed to determine the approach points and the limits of the
minefield. These coordinates are provided to the air-mission
commander during the air-mission brief. The pilot enters the grid
coordinates into the Doppler/GPS on the primary and the backup
aircraft. During execution, the air-mission commander monitors the
Doppler/GPS and determines the time to target, when to initiate
firing, and when to terminate firing.

Outside Friendly Territory

Reconnaissance of the proposed site for the air Volcano minefield will be
conducted before mines areemplaced. This could include—

• LRSD.

• Apache gun tapes.

• UAV overflights.

• I magery.

Key terrain or landmarks are used to identify start and end points for aviation
assets. It is unlikely that military marking will be employed based on the
proximity to enemy forces and the probability of early detection if man-made
markers are present. Fencing the minefield is not required until the area has
been secured by friendly forces.

Within Friendly Territory

Within friendly territory, air Volcano minefields should be fenced and marked
with NATO identification signs to protect friendly forces.

Fencing is installed before the air Volcano minefield is delivered, and it is
located 100 meters from the centerline of the minefield and 100 meters from
the start and end points (Figure D-8).

D-20 Air Volcano

o

CD

FM 20-32

1,785 m

X"

-*-

35 m

±

200 m

— X —

1,115m

-X-

-*■

100 m

35 m

35 m

100 m

-x-

30 m

1,315 m

-x-

Figure D-8. Fencing for an air Volcano minefield

Start and end points should be marked with man-made devices such as VS-17
panels. During limited visibility, start and end points should be marked with
infrared or heat-producing sources. Key terrain features and landmarks
should still be used to identify start and end points.

Fencing the minefield is not viable when the minefield duration is short or
civilians on the battlefield are an issue. I n this case, CA, public affairs, and
PSYOP personnel should be involved in letting friendly personnel know the
minefield location. This could include—

Leaflet drops.

• CA teams disseminating information.

• Host-nation support.

• PSYOP.

Air Volcano D-21

FM 20-32

REPORTING

SCATTERABLE MINEFIELD WARNING

Theemplacing unit is responsible for issuing theSCATMINWARN (Figure 8-
7, page 8-23) to adjacent units and higher headquarters. The brigade
engineers and the assistant division engineer assist in this process. They
disseminate the warning based on whether or not it is a brigade (brigade
engineer) or division (aviation brigade engineer) mission. To ensure that all
units are informed, the assistant division engineer forwards the
SCATMINWARN to the G3 for dissemination through operational channels.

SCATTERABLE MINEFIELD REPORT AND RECORD

The aircraft emplacing the minefield reports initiation and completion times
to the engineer of theemplacing unit. The engineer prepares thescatterable
minefield report and record (Figure 8-8, page 8-23) and forwards it through
his unit to the assistant division engineer. The assistant division engineer
forwards the report to the G3 who provides the information to higher and
subordinate units through operational channels.

D-22 Air Volcano

Appendix E

Safety and Training

Mine training is inherently dangerous, in part, because several different
types of mines and fuse systems are used throughout the world. Detailed
safety instructions for each type of mine are provided throughout this
manual. This appendix merely points out the safety aspects of live-mine
training that are common to all types of mines.

Conduct mine training as if the mines were live. This is the only way
soldiers form a habit of correctly and safely handling mines and gain a
true appreciation of the requirements and the time it takes to perform an
actual mine-warfare mission. Live-mine training gives soldiers the
confidence they need to handle mines and their components. Accidents can
usually be traced to ignorance, negligence, deliberate mishandling,
overconfidence, mechanical failure, or fright. The first four can be
overcome by training and proper supervision. Mechanical failure rarely
happens; but if it does, it can be controlled by training and proper
supervision. The last item, fright, is mastered through well -control led,
live-mine training.

STORAGE

There are three types of mines used in minetraining:

• I nert. Does not contain explosives.

• Practice. Contains an LE charge or a smoke-producing component to
simulate detonation.

• HE. Involves actual mines used in combat

Conventional mines are painted to enhance concealment, retard rusting of
exposed metal parts, and help identify the type of mine and filler (HE, LE, or
chemical agent). Older manufactured mines are painted according to the Five-
Element Marking System; newer mines use the Standard Ammunition Color-
Coding System (see Table E-l, page E-2).

NOTE : Mines that are color -coded and marked according to the old
system have been on hand for several years. Ensure that all
ammunition, whether color-coded according to the old or new
system, is properly and fully identified.

Always handle mines with care. The explosive elements in fuses, primers,
detonators, and boosters are particularly sensitive to mechanical shock,
friction, static electricity, and high temperatures. Boxes and crates containing
mines should not be dropped, dragged, tumbled, walked on, or struck. Do not
smoke within 50 meters of a mine or its components.

Safety and Training E-1

C2, FM 20-32

Table E-1. Mine color-coding system

Type of Ammunition

Five-Element Marking System
(Old)

Standard Ammunition Color-
Coding System (New)*

Persistent casualty chemical
agent

Gray with green markings and
two green bands

Gray with green markings and
two 12-mm green bands

Nerve agents

Gray with green markings and
two or three green bands

Gray with green markings and
three 12-mm green bands

Incendiary

Gray with violet markings and
one violet band

Light red with black markings and
one yellow band

HE

Olive drab with yellow markings

Olive drab with yellow markings

Practice mines

Blue with white markings

Blue with white markings

Inert mines

Black with the word INERT in
white

Blue with the word INERT in
white

*Chemical ammunition containing an HE has one 6-mm yellow band in addition to the other markings.

When it is necessary to leave mines in the open—

• Set them on dunnage at least 5 centimeters above the ground.

• Place a waterproof cover (such as canvas) over them, and leave enough
space for air circulation.

• Dig drainage trenches around stacks of mines to prevent water from
collecting under them.

• Protect mines and their components against moisture by
waterproofing them with grease coatings, tar paper, or tarpaulins.

Additional maintenance procedures are as follows:

• Do not open mine boxes in a magazine, at an ammunition dump, or
within 30 meters of an explosive store. Use copper or wooden safety
tools, if available, to unpack and repack mines.

• Do not fuse mines within 30 meters of an explosive or ammunition
holding area. Mines can be fused at the mine dump.

• Use specifics authorized by the US Army Materiel Command and
applicable TMs to disassemble mines and their components.

• Remove safety pi ns, safety forks (cl i ps), and other safety devices as the
last step when arming the mine; and replace them before the mine is
moved again. These devices prevent accidental initiation of the mine
while it is being handled.

• Place tape over open fuse cavities and secondary fuse wells. Ensure
that they are clear of obstruction and free of foreign matter before
attempting to install the fuse, the detonator, or theFD.

• Take steps to prevent moisture or water from accumulating around
the mine and subsequently freezing if the temperature fluctuates
around freezing. Mines usually function satisfactorily at temperatures
between 40 and 160SF. Most mines are not appreciably affected by
temperature changes, but mines can become neutralized by ice
formations (see Chapter 12).

E-2 Safety and Training

FM 20-32

• Observe proper procedures when recovering mines. Ensure that
components do not show evidence of damage or deterioration.

• Ensure that practice or inert mines or their components are not
present when live mines or their components are being used.

• Do not mix inert mines with live mines.

• Do not display live mines or their components in museums,
demonstrations, models, or similar layouts. Only inert equipment can
be used for displays.

• Handle explosive materials with appropriate care. The explosive
elements in primers, blasting caps, and fuses are particularly
sensitive to shock and high temperatures.

• Assemble activators, standard bases, and FDs before installing them.
Do not carry them in the pockets of your clothing.

• Do not poi nt F Ds at anyone.

• Camouflage the mine before removing the positive safety pin when
possible.

NOTE: Additional storage and safety precautions are outlined in TM
9-1300-206.

LIVE-MINE TRAINING

NOTE: No live-mine training is authorized with M14 mines. Units
outside Korea will not use live M16A1 mines in tactical or protective
minefield training.

Live-mine training is conducted by preparing, laying, arming, neutralizing,
and disarming live mines (with live fuses and components) in a training
environment.

Supervisors must adhere to the following safety considerations when
conducting live-mine training:

• Only personnel who are qualified and certified according to the local
range SOP are allowed to super vise activities or training in which live
mi nes or thei r components are used.

• Minimum personnel requirements toconduct live-minetraining are—

— Range officer (01 C).

— Range safety officer (RSO).

— One N CO supervisor for each arming bay.

— M ine-explosive breakdown N CO.

— One medic per four arming bays.

— Guards, as required by the range SOP.

• Sound organization is a must before live-minetraining can begin. The
01 C and supervising NCOs conduct a demonstration/briefing to
ensure that the practice runs smoothly.

Safety and Training E-3

FM 20-32

The training officer must foresee hazards that can occur through
personnel nervousness or material failure. The commander should
conduct a risk assessment according to AR 385-10.

The 01 C takes his place at the control point or post. Once he is
satisfied that all safety regulations have been observed, he orders the
first detail to start training.

Soldiers are trained on inert and practice mines before arming live
mines, according to the guidelines established by the Standards in
Training Commission.

Fuses are not inserted into mines until ordered by the 01 C.

An NCO supervisor must be present when soldiers arm live mines. He
ensures that soldiers adhere to the proper procedures and regulations.

Only one soldier arms a mine at any given time.

Personnel disarm one mine before arming the next one.

Personnel never arm an M 16 AP mine in the trip-wire mode during
live-mine training.

Personnel never remove the positive safety pin from the M 16 AP mine
during live-mine training.

Instructors inspect fuses and mines for serviceability before starting
practice.

Instructors inspect mines and their components for damage and
excessive wear after each student has gone through the station.
Replace the mine and the fuse if damage or wear is found.

All personnel wear a helmet (with the serviceable chin strap fastened)
and body armor when arming and disarming mines.

Ear protection is not permitted in the arming bays. The student must
be able to hear the supervisor and certain distinct noises (such as a
firing pin dropping).

Instructors post guards at all entrances to the range. The guards
communicate with the RSO by radio, wire, voice, or signal. No one
enters the range without permission from the RSO.

Instructors keep mine records and inventory sheets. They maintain
accountability of all mines and fuses, before and after each exercise.

Instructors draw and return supplies; check equipment for issue; and
ensure that live mines are safe, serviceable, and unarmed. They
ensure that the requirements contained in AR 385-63, range
regulations, and SOPs are observed and that no one does anything to
prejudice safety.

Instructors clearly mark the word LIVE on all live mines and their
components that are used for live-mine training. Live mines are
maintained separately from practice and inert mines.

E-4 Safety and Training

FM 20-32

Live AH Ds are not used with live mines during training, but they can
be used with practice and inert mines.

Arming and disarming are conducted in the prone position.

Waiting personnel are located in a bunker, behind a suitable
barricade, or at a safe distance from live-mine training.

Supervisors ensure that live-mine training is not rushed. There are no
shortcuts. Supervisors must allow soldiers ample time to arm and
disarm mines. Most soldiers are already in a high state of stress from
dealing with live munitions, and rushing them only serves to heighten
their stress level.

LIVE-MINE DEMONSTRATIONS

Live-mine demonstrations show mine characteristics and capabilities using
M16 and M18 AP mines and M15, M19, and M21 AT mines. The appropriate
authority must authorize the demonstration, and firing personnel must be
fully conversant with all safety and technical aspects pertaining to live-mine
firing.

An 01 C and an RSO are appointed for each activity involving live-mine firing.
The amount of explosive contained in the mine cannot exceed the maximum
amount allowed for the range, and one mine is fired at a time.

Upon arriving at the range, the instructor and his assistants establish areas
according to the following rules (signs are posted for large demonstrations):

• Firing point. Sited outside the danger area and near the 01 C to
facilitate coordination, commentaries, and firing.

• Spectator area. Sited outside the danger area and within earshot of
the commentator. It is large enough to provide a good view of the
explosion.

• Supply area. Any suitable area away from spectators.
Explosive area. Sited away from supplies and spectators.

• Mine area. Mines are set out in full view of the OIC and spectators.
I ndividual mines are at least 25 meters apart.

• Target area. Targets are positioned and inspected by spectators before
the blasting cap is inserted into the mine.

M 16 Antipersonnel Mine

• Safety distance. 300 meters.
Firing procedures.

Roll out 300 meters of firing cable and attach it to a stake or picket
in the ground (leave at least 1 meter of free end). Test the firing
cable for continuity.

Place the mine in the ground (dig in level with the surface).
Remove the shipping plug.

Test a blasting cap (under a sandbag) with the demolition test set.

Safety and Training E-5

FM 20-32

Attach the ends of the blasting-cap leads to the ends of the electric
cable and insulate the joints with tape. Place the blasting cap into
the fuse well (see Figure E-l, pageE-6).

Taped joints

NOTE: The cap is suspended
two thirds of the way down
the fuse well.

Figure E-1. M16 AP mine

• Suggested target. A circle of tar paper, 6 meters in diameter,
supported by 1.8-meter pickets. Spectators can later view shrapnel
effects.

NOTE : The procedure detailed here dispenses with the M605 igniter.
The mine cannot be detonated by pull or pressure. The expulsion
charge and millisecond delay fuses are still operated, and the mine
bounds out of its casing (which remains in the ground) before
exploding in the air. Although the normal firing delay is removed, it
does not detract from the demonstration. The blasting cap is
suspended two-thirds of the way down the fuse well to initiate the
expelling charge and delay elements.

• Misfires. In the event of a misfire, the RSO disposes of the mine by
placing a block of C4as closetothemineas possible, without touching
it. He destroys the mine by normal nonelectric means.

M18A1 Antipersonnel Munition

Safety distance. 300 meters.
Firing procedures.

— Roll out 300 meters of firing cableand attach it toa stakeor picket
in the ground (leave at least 1 meter of free end). Test the firing
cable for continuity.

— Place the mine on the ground and ensure that the front of the
mi ne faces away from the f i ri ng poi nt. Remove the shi ppi ng pi ug.

— Test an electric blasting cap (under a sandbag) with thedemolition
test set.

E-6 Safety and Training

FM 20-32

Attach the ends of the blasting cap leads to the ends of the electric
cable and insulate the joints with tape. Place the blasting cap into
the detonator well (see Figure E-2).

Figure E-2. M18A1 AP mine

• Suggested target. Several E-type silhouette targets, 15 to 100 meters
from the mine.

NOTE: The procedure detailed here applies only to demonstration
firings. Standard accessories are used on all other occasions. The
mine explodes instantaneously and clearly illustrates the sound of an
M18A1 explosion.

• Misfires. In the event of a misfire, the RSO disposes of the mine by
placing a block of C4as closetothemineas possible, without touching
it. He destroys the mine by normal nonelectric means.

M15, M19, and M21 Antitank Mines

• Safety distance. 1,000 meters.

• Firing procedures.

— Roll out 1,000 meters of firing cable and attach it to a stake or
picket in the ground (leave at least 1 meter of free end). Test the
firing cablefor continuity.

— Placetheminein theground and leave the top exposed. A target is
used only when the mine can be placed without disturbing the
target. A derelict vehicle is a suitable target.

— Place a block of C4on top of M15s and M19s (see Figure E -3, page
E-8).

— Remove the shipping plug from the booster well of the M21 and
pack the well with C4. Insert an electric blasting cap into the C4
(see Figure E-4, page E-8).

NOTE : Do not remove safety devices. Keep arming dials in the SAFE
position. The mine explodes instantaneously and clearly
demonstrates the blast/shaped-charge effect.

Safety and Training E-7

FM 20-32

Taped joints

Stake

Figure E-3. M15 and M19 AT mines

Taped joints

nL

Figure E-4. M21 AT mine

• Misfires. In the event of a misfire, the RSO disposes of the mine by
placing a block of C4as closetothemineas possible, without touching
it. He destroys the mine by normal nonelectric means.

RISK ASSESSMENT FOR LIVE -MINE DEMONSTRATIONS

The following risk assessment is provided as a guideline for live-mine
demonstrations using an M 16 AP mine. It must be carefully reviewed before
conducting a demonstration. Live-mine demonstrations can be conducted in a
safe manner. The risk of injury to personnel is significantly minimized if you
adhere to established procedures.

During the demonstration, mines are not armed with standard fuses. They are
activated by electric blasting caps placed inside the fuse wells.

A demonstration shows the effectiveness of an M 16 AP mine. Spectators do
not handle the mines or explosives. To show the effectiveness of an M16 mine,
a sheet of paper is placed in a semicircle around the mine. Spectators remain
in bunkers or at a safe distance while mines are primed with electric blasting
caps and detonated. After the mines have been detonated and the RSO has
cleared the area, spectators are allowed to view the results of the detonated
mine. Misfires are handled by the RSO.

Figure E-5 is a risk assessment prepared by the Department of
Transportation.

E-8 Safety and Training

FM 20-32

QUALITATIVE RISK ASSESSMENT

Qualitative risk-assessment techniques are used to place a value on the level of risks created by hazards in an
operation. The principal qualitative technique is the risk-assessment code (RAC) described in MILSTD-882C.
This method was established as a common way to set priorities for Department of Defense (DOD)-wide
hazard-abatement programs and uses an RAC matrix format to combine the concepts of frequency and
severity into a single, numerical code. It is very useful in comparing different risks (such as those from different
programs) or even differences (such as health versus safety risks).

RACs are implemented for the Army in Army Regulation (AR) 385-10, which describes the two qualities of
hazard severity and hazard probability as follows:

• Category I — CATASTROPHIC. May cause death or loss of a facility. In this case, loss does not mean a
period of interrupted service; it means destruction of the facility or operation.

• Category II — CRITICAL. May cause severe injury, severe occupational illness, or major property
damage.

Category III — MARGINAL. May cause minor injury, minor occupational illness, or minor property
damage.

• Category IV — NEGLIGIBLE. Probably would not affect personnel safety or health, but is in violation of
specific standards.

Mishap probability is the probability that a hazard will result in a mishap, based on an assessment of factors
such as location, exposure in terms of cycles or hours of operation, and affected population. The expression
combines the idea of the probability of an event and the exposure to the event. These probabilities are
expressed as letters conforming to the following system:

• Subcategory A — Likely to occur immediately.

• Subcategory B — Probably will occur in time.

• Subcategory C — May occur in time.

• Subcategory D — Remote.

• Subcategory E — Improbable.

The two qualities are combined to yield an RAC by using the following table:

Risk-Assessment Code Table

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In using the RAC system, it is important to note that the IA and 1 1 A classifications are termed "imminent
danger." Though their RAC codes of 1 are the same as that of the IB entry, their immediacy makes them more
critical. The codes are useful in assessing an operation as it begins, but they must be updated as the operation
continues, the facility ages, and so forth to account for degrading condition or performance.

For risk managers, there are some important organizational/management considerations to RAC codes. AR
40-10 also contains an RAC system, but due to a difference in definitions, the health RAC code may be a lower
number, indicating a higher degree of risk. This is important to managers who are comparing health risks to
others risks under AR 385-10; the health issue would always win if no compensation or consideration was
factored into the codes. From the managerial standpoint, it must be remembered that RACs are judgmental
and not necessarily held to be the same by different managers or evaluators. When differences in perception
occur, the differences are likely based on either the understanding of the operation's behavior or the criteria for
selecting the probability and severity. It is wise to listen to the basis of others' RAC choices and attempt to
develop a common understanding.

Figure E-5. Excerpt from Risk-Assessment Techniques Manual, prepared by the Department of
Transportation's Transportation Safety Institute, August 1986

Safety and Training E-9

FM 20-32

Qualitative risk-assessment techniques are used to prepare estimates of risk levels using performance
data, when available, to improve the accuracy of risk estimates used in risk-acceptance decision making.
These assessments are numeric values representing the safety risk of an Army activity, system operation,
or comparable endeavor, based on actuarial or derived numeric data. Though RACs are numerical, they
are derived from judgments and are not demonstrable in records of performance. If it is desirable that
performance be measured, it is necessary that quantified estimates of risk levels be established, that risk
levels be predictive so that future performance has a base of comparison, and that risk levels be assigned
numeric values.

Figure E-5. Excerpt from Risk-Assessment Techniques Manual, prepared by the Department of
Transportation's Transportation Safety Institute, August 1986 (continued)

RISK ASSESSMENT FOR LIVE-MINE TRAINING

The United States Army Engineer Center, Department of Instruction,
obtained information for the following risk assessment from the Collective
Training Branch, Department of Training and Doctrine, and from the
Engineering Branch for Engineer Officer Basic Course demolitions training.
Hazards are identified and analyzed on preliminary hazard-analysis work
sheets (see Figures E-6 through E-15, pages E-ll through E-21). Risk-
assessment codes are assigned to each hazard based on the severity and the
probability of occurrence.

References used in the risk-analysis process include this manual and the
following publications:

DA Pamphlet (Pam) 350-38.

AR 385-10.

AR 385-16.

AR 385-63.

Soldier Training Publication (STP) 5-12B1-SM.

Training Circular (TC) 25-8.

TM 9-1345-203-12.

TM 43-0001-36.

E-10 Safety and Training

FM 20-32

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need is identified by a unit's
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personnel.

Training is conducted in the
proper environment.

Soldiers are in the proper
protective gear.

No trip wires or live AHDs are
used with an M16 mine.

In the event of damage or loss of
any safety pins, stop training with
this particular mine and destroy
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training.

Do not remove the
positive safety pin at
any time.

Do not remove the
positive safety pin at
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One instructor is assigned to one
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Soldiers are proficient on inert
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One instructor is assigned to one
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Mine training is done after
identified by a unit's METL and
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Do not remove the
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OR

Remove the
extension rod before
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Stop training with this particular
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See risk assessment for
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After testing, ensure that wire
ends are twisted together.

Only one demolitions person and
one safety person will be at the
mine when the blasting cap is
inserted into the demolition.

RSO is responsible for clearing
misfires.

RSO keeps a misfire kit under his
control.

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Handle cap
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Place cap under
sandbag.

Ensure that firing
wire is shunted.

Ensure proper
handling of blasting
cap.

Ensure proper
handling of blasting
cap.

OIC declares a
misfire.

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Cap improperly handled

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This list is not conclusive and will
depend on the particulars of the
unit, the training, and the range
facilities.

Additional peripheral factors a
unit commander may wish to
consider are —

Level of proficiency.

• Time of event (day or
night).

• Availability and extent of
emergency-response
assets.

• Train up (rehearsals and
dry runs).

• Terrain.

Location of instructor in
relation to soldier during
the training.

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Postpone or cancel
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Temperature between 45 and
70 °F

Clear or partly cloudy

Wind speed less than 5 mph

Temperature between 32 and
44°For71 and 80 °F

Drizzle

Wind speed between 5 and 1 5
mph

Temperature less than 32 °F or
greater than 80 °F

Moderate to heavy rain

Snow or ice

Wind speed greater than 1 5
mph

Current doctrine not available

Questions or confirmation of
techniques not quantified

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Wet munitions

The sequential
arming or
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support material is
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Stop training if the
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Ensure that soldiers
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Allow for breaks
during training.

Stop training if
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Safety and Training E-21

FM 20-32

E-22 Safety and Training

Appendix F

Mine Awareness

Mine awareness should actually be entitled mine/UXO awareness. If only
mines are emphasized, ordnance (bomblets, submunitions) may be
overlooked, and it has equal if not greater killing potential. The main
objective of mine awareness is to save lives, so it is important to ensure
that soldiers are well-informed and thoroughly trained. This appendix
outlines the tasks needed for soldiers and units to survive in a mined/UXO
environment.

M ine awareness should be emphasized at all levels of command, and it
involves soldier and leader skills. Soldier skills area mix of individual and
collective tasks that are required for an element to maintain its combat
effectiveness in and around a mined environment. It is important to note
that a soldier's basic mine-awareness skills are critical to his and the unit's
survival. Leader skills involve planning missions, assessing situations,
and tracking/disseminating mine information. A unit must be proficient in
all mine-awareness skills to effectively operate in a mined environment.

SOLDIER

Soldier skills involve individual and collective tasks that are required for basic
survival in a mined/UXO environment. They include minefield indicators,
probing techniques, mine-detector operation, extraction drills, survival rules,
casualty treatment, and evacuation drills.

Visual Indicators

M i ne/U XO i ndicators are part of al I combat operations. U nderstandi ng and
recognizing mine indicators could determine whether or not a soldier becomes
a casualty. The following may indicate the presence of mines/UXO:

• Tripwires.

• Signs of road repair (such as new fill or paving, road patches, ditching,
culvert work).

• Signs placed on trees, posts, or stakes. Threat forces mark their
minefields to protect their own forces.

• Dead animals.

• Damaged vehicles.

• Disturbances in previous tire tracks or tracks that stop unexplainably.

• Wires leading away from the side of the road. They may be firing wires
that are partially buried.

Mine Awareness F-1

FM 20-32

Probing

Odd features in the ground or patterns that are not present in nature.
Plant growth may wilt or change color, rain may wash away some of
the cover, the cover may sink or crack around the edges, or the
material covering the mines may look like mounds of dirt.

Civilians. They may know where mines or booby traps are located in
the residential area. Civilians staying away from certain places or out
of certain buildings are good indications of the presence of mines or
booby traps. Question civilians to determine theexact locations.

Pieces of wood or other debris on a road. They may be indicative of
pressure or pressure-release F Ds. These devices may be on the surface
or partially buried.

Patterns of objects that could be used as a sighting line. The enemy
can use mines that are fired by command, so road shoulders and areas
close to the objects should be searched.

Probing is very time-consuming and is used primarily for clearing operations,
self-extraction, and covert breaching operations. Detection of mines by visual
or electronic methods should be confirmed by probing. Use the following
procedures and techniques when probing for mines:

• Roll up your sleeves and remove your jewelry to increase sensitivity.
Wear a Kevlar helmet, with the chin strap buckled, and a protective
fragmentation vest.

• Stay close to the ground and move in a prone position to reduce the
effects of an accidental blast. When moving into a prone position, the
prober should—

— Squat down without touching his knees to the ground.

— Scan forward up to 2 meters and to the sides up to 3 meters for
mine indicators.

— Probe the area around his feet and as far forward as possible.

— Kneel on the ground after the area is found to be clear and
continue probing forward until he is in a prone position.

Use sight and touch to detect trip wires, fuses, and pressure prongs.

Use a slender, nonmetallic object as a probe.

• P robe every 5 centi meters across a 1-meter front.

• Gently push the probe intotheground at an anglethat is less than 45
degrees.

DANGER
Use extreme caution when probing. If the probe is pushed
straight down, its tip may detonate a pressure fuse.

Apply just enough pressure on the probe to sink it slowly into the
ground.

F-2 Mine Awareness

C3, FM 20-32

• If the probe encounters resistance and does not go into the ground
freely, carefully pick the soil away with the tip of the probe and remove
the loose dirt by hand. Care must betaken to prevent functioning the
mine.

• When a solid object is touched, stop probing and use two fingers from
each hand to carefully remove the surrounding soil and identify the
object.

• If the object is a mine, remove enough soil to show the mine type and
mark its location. Do not attempt to remove or disarm the mine. Use
explosives to destroy detected mines in pi ace or use a grappling hook
and rope to cause mines to self-detonate. Metal grappling hooks
should not be used on magnetic-fused mines.

Probing is extremely stressful and tedious. The senior leader must set a limit
to the time a prober is actually probing in the minefield. To determine a
reasonable time, the leader must consider METT-TC factors, weather
conditions, the threat level, the unit's stress level, and the prober's fatigue
level and stateof mind. Asa rule, 20 to 30 minutes is the maximum amount of
time that an individual can probe effectively.

AN/PSS-12 Metallic Mine Detector

The AN/PSS-12 mine detector (Figure F-l, page F-4) is a man-portable
metallic mine-detection system that is used to detect AT and AP land mines.
Its search head contains two concentric coils— the transmitting (outer) coil
and the receiving (inner) coil. During operation, the transmitting coil emits a
magnetic field symmetrically above and below the search head. When this
field encounters metal objects, it induces currents in these objects. When the
induced currents reach the receiving coil, an auditory signal is provided to the
operator. The detector is able to detect large metal mines from a distance of
several feet, but can detect low-metal mines from only a few inches.

Unpacking

WARNING
It is important to understand that the mine
detector is only effective when there is a
sufficient amount of metal in the mine.

The system is stored and transported in a single carrying case.

Open the pressure-relief valve in the carrying case.

Release the latches on the carrying caseand open the top.

Remove the bag that contains system components.

Unzip the bag and ensure that all components are present (Figure F-2,
page F-4).

Remove the following items from the bag carefully:

— Telescopic pole and search-head assembly with cable and plug.

— Electronic unit.

Mine Awareness F-3

C3, FM 20-32

Figure F-1. AN/PSS-12 metallic mine detector

Telescopic
pole and
search-
head
assembly

Electronic
U) unit

Spare
plastic bolt,
spare cable
clamps,
and a 5-cm
test piece

Headset
with cable
and plug

Figure F-2. AN/PSS-12 packed components

— Headset with cable and plug.

Ensure that the bag contains the following spare parts and test items:

— Spare plastic bolt.

— Spare cable clamps.

— 5-centimeter test piece.

I nspect the search head for cracks or damage.

F-4 Mine Awareness

C3, FM 20-32

Electronic-Unit Setup

I nspect cable connectors for damage and check for bent pins.

I nspect hook and pile material on headphones for serviceability.

I nspect cables to ensure that they are not cut, broken, or frayed.

I nspect the electronic unit for cracks, damage, and completeness. This
includes ensuring that all switches and knobs are present and
functional.

Ensure that telescopic pole is not bent, dented, or damaged and can be
extended and retracted.

Ensure that the power switch on the electronic unit is in the OFF
position (Figure F-3).

LOUDNESS

HEADPHONE

ON

SENSITIVITY

SEARCH HEAD

Indicator lamp

Figure F-3. Electronic unit

• Release the latches on the battery-compartment cover and remove the
cover (Figure F-4).

Figure F-4. Battery installation

Mine Awareness F-5

C3, FM 20-32

I nsert batteries according to markings.

WARNING
Ensure that the battery cover is completely closed and the latches
are in the proper position. This prevents the inadvertent opening
of the battery compartment during operation. Failure to do this
could result in injury, damage to the equipment, and/or improper
operation.

Reinstall and latch the battery cover. Ensure that the latches are in
the proper closed position.

Press in the catch (located just below the arm support) to unlock the
telescopic pole from the transport position. Turn the outer tube until
the catch snaps into the guide groove. Pull the telescopic pole out to a
suitable length. Ensure that the telescopic pole is locked in one of
three fixed positions.

Connect the headphones and the detector-head cables to the electronic
unit. Fit the protective caps of the cable connectors to the
corresponding rubber caps on the electronic unit.

Put on the headphones. Place the straps of the headphones over the
forehead and on top of the head. The hook and pile material goes
behind the head at the nape of the neck.

Connect the detector-head cable to the lower (plastic) portion of the
telescopic pole.

— Attach the lower cable clamp 5 centimeters above the wing nut.

— Attach the second cable clamp 5 centimeters down from the
junction of the lower and upper (aluminum) portion of the
telescopic pole.

— Attach the third cable clamp between the other two cable clamps.
Do not attach the cable to this middle clamp. This clamp will
become the sensitivity marker clamp.

WARNING
The cable should not be attached to the aluminum portion of the pole,
because it causes the sensitivity of the mine detector to fluctuate.

Adjust the position of the handle by loosening the knurl nut.
Retighten the nut when the handle is properly positioned.

Adjust the position of the search head so that it will be parallel to the
ground.

Attach the electronic unit to the operator's load-bearing equipment
(LBE) belt using the belt clips. Right-handed soldiers should put the
electronic unit on the left hip. Left-handed soldiers should put the
electronic unit on the right hip. Put the safety strap over the shoulder.

F-6 Mine Awareness

C3, FM 20-32

Electronic-Unit Controls and Indicators

The AN/PSS-12 electronic unit has the following controls and indicators
(Figure F-3, pageF-5):

• On/off switch. This switch is the power control for the AN/PSS-12. It
must be in the ON position when detection is being conducted.

• Loudness control. This is the volume control for the audible alarm. It
should be adjusted to a comfortable listening level during use.

• Sensitivity control. The sensitivity control is used to adjust the
detection characteristics of the mine-detector head. Details on how to
set the sensitivity are provided below.

• Indicator lamp. This lamp indicates low battery voltage or a system
malfunction. It provides a short flash when the unit is turned on and
flashes continuously when the batteries are low or there is a
malfunction.

• Audiblesignals.

— The system provides an audible signal through the headset when
the search head is over or very near a metal object. The signal is a
continuous tone that at first resembles a growl. The tone increases
to a higher pitch as the search head is moved closer to a metal
source (such as a mine) and decreases in pitch when moved away.

— The AN/PSS-12 has a check tone that is provided every 1 to 2
seconds. The tone resembles a clicking sound, and its purpose is to
continuously inform the operator that the system is functioning
satisfactorily. If the check tone disappears or its frequency
decreases, discontinue searching and determinethe malfunction.

— A flashing indicator lamp and a continuous tone (the same tone
heard with a target return, except it does not abate when moved
away) on the headphone indicates low battery voltage. If the unit's
indicator lamp flashes, change the batteries and readjust the unit.

Operation

Once the system is assembled, it is ready for adjustments prior to operation.
Remove rings, watches, and other jewelry before adjusting or using the
system.

Power Up/Sensitivity Adjustments

• Turn the sensitivity and loudness knobs completely counterclockwise.

• Look at the indicator lamp on the electronic unit and turn the on/off
switch to the ON position. The lamp should give a short flash. If it
does not, ensure that the batteries arecorrectly installed or insert new
batteries. If the lamp flashes continuously, the battery voltage may be
low.

• Hold the search head approximately 0.6 meter above the ground, and
turn the sensitivity knob clockwise until a continuous tone is heard.

Mine Awareness F-7

C3, FM 20-32

While this is being done, adjust the loudness control to a comfortable
listening level.

• Turn the sensitivity knob slightly counterclockwise until the tone
ceases. The check tone (a clicking sound) should still be heard every 1
to 2 seconds. Readjust the loudness control if necessary. If the check
tone disappears or its frequency decreases, discontinue searching and
determi ne the malfunction.

• Set the sensitivity in either of the following two ways:

— The preferred method is to use the most difficult to detect type of
mine (made safe without changing the metal content) that is
expected to be encountered.

— In the absence an actual mine, use the 5-centimeter test piece that
comes with the AN/PSS-12 packed components.

• Bury the mine (if you have a mine) at the deepest depth that threat
mines are expected to be found. If you do not have a mine, bury the
5-centimeter test piece vertically so that the metal portion is at the
deepest depth which threat mines are expected to be found. I n the
absence of more specific information, bury the test piece at a depth of
5 centimeters). This places the top of the test piece flush with the
ground's surface.

• Place the detector head lightly on the ground directly above the mine/
test piece and adjust the sensitivity knob so that the mine is detected
and you have an easily heard signal from the headset. Now, move the
detector away from the mine/test piece until the signal ceases to be
heard.

• Float the detector head lightly on the ground at a 0.3-meter-per-
second movement rate across the mine/test piece. With the detector
head in motion, check to see if the signal can again be easily heard. If
not, increasethe sensitivity until the signal can be easily heard.

NOTE : The higher the sensitivity is set (between just being able to
detect the mine/test piece and where the signal from the soil first
becomes audible) the less the chance of missing a mine, but the more
the chance of a false alarm rate.

WARNING
In some conditions, you may not be able to detect a target mine/test
piece at the deepest depth the threat mine is expected to be
encountered. Do not use the AN/PSS-12 to detect mines in those
conditions.

NOTE: Adjusting the sensitivity with the mine/test piece buried in
soil that is similar to the soil where the detector will be used is very
important. Otherwise, the sensitivity setting is simply a guess,
because different soil types and moisture content influence the
sensitivity of the detector.

F-8 Mine Awareness

C3, FM 20-32

Sensitivity Level

The AN/PSS-12's sensitivity setting drifts over time. During use, soldiers
should check the detector's sensitivity every 1 to 2 meters of forward advance
in the mine lane.

• With the sensitivity properly set using a buried mine/test piece, the
detector is moved to an adjacent place on the ground over a clear area.

• To check the detector, a metal object (bayonet or other metal object) is
slid down the lower (plastic) portion of the telescopic pole until the
operator hears the same auditory signal that was emitted when the
search head was placed over the buried mine/test piece.

• At this point on the lower plastic shaft, the middle plastic cable clamp
(the middle clamp previously attached without the cable) is
positioned. This clamp now becomes the sensitivity marker clamp.

• At approximately every 1 to 2 meters of forward advance in the mine
lane (or more often if desired), the same metal object (bayonet) is
moved down the shaft to the sensitivity marker clamp and the
operator listens to determine if the same auditory signal is emitted.
When the same auditory signal is not heard, the sensitivity knob is
adjusted up or down until the same auditory signal is replicated and
maintained.

NOTE: It is important that the operator maintain a consistent body
posture and angle between the telescopic pole and the search head
each time a sensitivity check is made.

DANGER
Low batteries may reduce detector performance well
before the indicator light comes on. If you need to
frequently adjust the sensitivity knob to maintain a
constant sensitivity setting or if the indicator light comes
on, discard all batteries and replace them with new ones.
Failure to do this could result in injury or death.

DANGER
Discontinue searching and readjust the sensitivity if the
check tone disappears or its frequency decreases. Failure
to do this could result in injury or death.

Search Methods

Sweep across the lane, keeping the entire search head in light contact
with the ground. Sweeping speed should be approximately 0.3 meter
per second. Each sweep must be a minimum of 1.5 meters and must
overlap the edge of the lane by at least one-half the width of the search
head. Each sweep should advance forward at no more than 6 inches
per sweep. The sweep and advance must be maintained as described,
otherwise gaps will be left between sweep paths or at the edge of the
lane and a low-metal mine can be missed.

Mine Awareness F-9

C3, FM 20-32

• Perform a sensitivity check at approximately every 1 to 2 meters of
forward advance in the mine lane (or more often if desired) and make
adjustments as necessary. It is important that the operator maintain a
consistent body posture and angle between the telescopic pole and the
search head each time a sensitivity check is made.

• Pat the search head lightly on the ground (each pat advancing no more
than one-half the width of the search head) in low vegetation or rocky
or uneven ground where smooth sweeping cannot be performed.
Ensure that the wing nut is tight, so that the position between the
head and telescopic pole is fixed.

NOTE: Many conditions of vegetation may not allow getting the
search head on the ground. Do not push through vegetation to get the
search head on the ground. Different environments will require
slightly different techniques. If you cannot get the search head on or
very near the surface of the ground, the detector will not detect low-
metal mines.

NOTE: The AN-PSS/12 detector's performance is reduced when the
cable between the electronic unit and the top cable clamp is
permitted to hang unrestrained during sweeps. The soldier can
control this problem by holding the cable in his free hand.

WARNING
Always be aware of the potential for booby traps. The search head
should never be swept where its path cannot be visually cleared. If trip
wires are a threat, other techniques to detect trip wires should be used
before sweeping.

Alarm Investigation/Mine Identification

When an auditory signal is heard, the soldier must investigate further to
determine if the signal is a reliable indication of a mine.

• End the sweep procedure and begin the investigation procedure at the
first auditory indication from the detector of metal in the ground. The
purpose of the investigation is to determine if the signal is repeatable
and, therefore, a likely indication of a mine. If so, the investigation
continues with the purpose of gaining more information concerning
the size, type (high-metal or low-metal mine), and specific location of
the signal source.

NOTE: In some cases, the detector may provide a weak signal that
cannot be repeated during the initial investigation process. Do not
give up on the reliability of the signal until the sensitivity of the
detector has been checked to ensure that it has not drifted to the low
side.

NOTE :A footprint is defined as the entire area on the ground where a
mine or metallic source causes the detector to generate an auditory
signal. Small footprints, often as small as 10 to 15 centimeters in
diameter, will indicate low-metal mines. Footprints as large as 60 to
122 centimeters in diameter may indicate high-metal mines.

F-10 Mine Awareness

C3, FM 20-32

Note the location on the ground (at the center of the search head)
where the signal is first heard. Then attempt to develop a set of points
on theground that identifies the source footprint.

— Develop this footprint by first moving the search head away from
the signal source until no signal is heard and then sliding the
search head toward the signal from several clock positions.

— Note the specific location of the center of the search head at each
location where the auditory signal begins. Once the signal is
detected, the detector is no longer slid toward the potential source
to avoid coming closer than necessary to a potential mine.

— Repeat this process and mark or note the locations on the ground
until the size and shape of the footprint can be understood.
Typically, the pattern will resemble a semicircle with the 6 o'clock
position nearest the operator.

WARNING
The large footprints of high-metal mines may mask signals from low-
metal mines within the footprint. Always assume that there are low-
metal mines within the large footprint area.

Identify the center of very large footprints (if important). The airborne
technique may be quicker than the method previously discussed to
identify the perimeter.

— The search head must be adjusted so that it can be held above the
ground with the head parallel to the surface.

— The detector can then be manipulated above the source until the
signal can be heard at only a single point. Movethe search head in
a crossing pattern, which should produce a smaller and smaller
signal area as the pattern is repeated at gradually increasing
heights. Near the surface, the signal can be heard over a broad
lateral area, but as the search head is raised higher off theground,
this area becomes progressively smaller. As the search head is
raised higher off theground, the area where the signal can still be
heard is reduced to a point.

— The center of the mine or metal source should be directly below
this point. Do not ignore the potential for low-metal mines to be
hidden in this large footprint on theground.

WARNING
Always be aware of the potential for booby traps and UXO. The search
head should never be swept where its path cannot be visually cleared.
If trip wires are a threat, other techniques to detect trip wires should be
used before sweeping.

Mine Awareness F-11

C3, FM 20-32

Other Operational Actions

• Keep mine detectors at least 2 meters apart during setting,
adjustment, and operational phases to prevent interference.

• Change the batteries immediately if the indicator lamp flashes, a
constant audibletoneis heard, or the check tone (clicking sound) stops
and readjust the sensitivity. The search sensitivity is affected long
before the lamp begins flashing, and the unit will be unusable until
fresh batteries are installed.

• Ensure that only the lower part of the telescopic pole is used when the
equipment is operated by a soldier in the prone position.

• Turn the unit off after completing the search operations.
Disassembly and Packing

• Ensure that the on/off switch on the electronic unit is in the OFF
position.

• Disconnect the headphones from the electronic unit.

• Detach the cable connection on the electronic unit for the magnetic
search head, and replace the protective caps on the plug and socket.

• Release the electronic unit's battery-cover latches, and remove the
battery cover.

• Remove the batteries, and ensure that none of the battery cases have
ruptured; if they have, notify your supervisor. Reinstall the battery
cover and latch it.

• Remove the cable clips from the telescopic pole.

• Col I apse the telescopic poleto its travel length, and turn its outer tube
until it is locked by the catch. Loosen the plastic restraining bolt, and
fold in the magnetic search head.

• Pack the components in the carry bag as shown in Figure F -2, page F-
4. For long-term storage, do not put batteries in the carry bag. Close
and zip the carry bag.

• Place the carry bag in the metal transport case, and latch the case.
Close the pressure-relief valve.

As in probing, the senior leader must set a limit to the time an individual can
use the mine detector. The time limit is determined by METT-TC factors,
weather conditions, the threat level, the unit's stress level, and the
individual's fatigue level and state of mind. As a rule, 20 to 30 minutes is the
maximum amount of time an individual can use the detector effectively.

F-12 Mine Awareness

C3, FM 20-32

Evacuation Drills

A well -developed, well-rehearsed evacuation drill is necessary to extract an
individual or a unit from a mined area. Units must develop evacuation drills
for dismounted and mounted operations. Each type of operation should
include two drills— one using a mine detector (mounted extraction) and one
without using a mine detector (dismounted extraction).

Mounted Extraction

The convoy commander halts the convoy and reports to higher
headquarters.

No vehicles move and no troops dismount unless directed to do so.

Elements provide 360-degree security from vehicles.

Troops thrown from vehicles should not move. Personnel are extracted
by using dismounted evacuation procedures if electronic detectors are
not available.

The senior leader, if engineers are not available, assesses the situation
and directs vehicles to back up along the entry-route tracks. If an
immediate threat exists, occupants of damaged vehicles evacuate out
the rear of the vehicle and along the vehicle-entry tracks. If no
immediate threat exists, occupants of damaged vehicles remain in the
vehicle until it is extracted.

Engineers, if available, sweep the area and provide a cleared path for
movement. They—

— Clear a lane that is wide enough for the towing vehicle.

— Useall available tow cables to increase the distance before towing
if an M88 is unavailable. Remember, an M88 has a wider track
base than other tracked vehicles.

— Ensurethat all towing-shacklesets are complete and mounted.

— Ensurethat the towing vehicle has tow cables on the front and the
rear if possible.

— Ensure that rear cables are attached to the lower mounts. This
allows the crew to recover the vehicle without touching the
ground.

— Pull thevehicleout at least two-vehicle lengths before switching to
a tow bar. When towing a vehicle after a mine strike, the chance of
fire is greater because of possible damage to the vehicle.

— Provide first aid and conduct casualty evacuation or have medics
provide treatment and medical evacuation.

— Guide vehicles through the safe area.

— M ark, record, and report the threat.
Continuethe mission.

Mine Awareness F-13

C3, FM 20-32

Dismounted Extraction

All personnel freeze and crouch into a low-silhouette position. Be
cautious when making this movement to ensure that you do not
detonate another mine. If a protective mask is worn on your hip, do
not allow it to come in contact with the ground because contact may
detonate a mine. Do not help casualties because you could also become
a casualty.

The leader designates a security element and a soldier to assist in
casualty evacuation.

Soldiers extract along the path they entered. If possible, they step in
thesame places as before; if impossible, they probetheir way out.

The security element, consisting of individuals who are not in the
minefield, sets up security for the unit.

The soldier extracting the casualty—

— Probes a 1-meter-wide path to the casualty and marks the cleared
path with foot powder or marking tape as it is probed.

— Probes around the casualty to clear the area.

— Performs first aid.

— Carries the casualty out of the minefield along the cleared path.
(Stretcher parties do not enter the area unless a 2-meter-wide
path has been cleared to the casualty.)

The unit marks the threat and assembles back at the rally point.

The unit reports the incident when it is 50 to 100 meters away from
the minefield. If soldiers are in the minefield and radio transmission is
required, move the transmitter at least 300 meters from the minefield.
This prevents accidental mine detonation from the radio signal.

The unit provides first aid and conducts casualty evacuation or has
medics provide treatment and medical evacuation.

• The unit continues the mission.
Extraction from Scatterable Mines

• The individual whodiscovers the mine initiates the alarm according to
the unit SOP.

• Unit personnel at the command post receive the alarm and alert
others.

• The unit TOC requests counterbattery fire if the mines are artillery-
delivered.

• Vehicle commanders check the immediate area. They do not dismount.
I nspect the vehicle for mines and/or trip wires. Note and record the
location of all mines found on or around the vehicle.

• Personnel leave any vehicle that is touching or is blocked by AT mines
in place until the remainder of the unit is out of the minefield.

F-14 Mine Awareness

C3, FM 20-32

Unit leaders identify immovable vehicles and designate one or more
lanes for remaining personnel and vehicles to use when exiting the
minefield.

Leaders identify a clearance team to extract remaining vehicles and
personnel. The clearance team—

— Uses visual means to locate mines and marks vehicle lanes at
least 4 meters wide. Personnel mark lanes according tothe tactical
situation and the threat in the area; however, they mark them so
that team personnel can reenter the minefield and recover
equipment and vehicles.

— Destroys or removes all mines in lanes, using a grapnel hook or
other means as necessary, in the sequence directed by the team
leader. Personnel detonate unmovable mines to reduce personnel
injury and equipment damage.

Vehicle commanders direct personnel to ground-guide vehicles out of
the minefield. Ground guides—

— Ensure that individual elements move only when directed by the
chain of command.

— Place equipment that is not in contact with a mine or a trip wire
onto vehicles.

— Direct vehicles to the designated exit lane or, if safer, allow
vehicles to exit the minefield on their own.

Clearance team personnel, aided by unit personnel, remove
equipment and vehicles remaining after initial extraction from the
minefield. They—

— Reenter the minefield using the same exit routes.

— Detonate the minimum number of mines necessary to remove
vehicles and equipment from the minefield.

— Avoid touching mines. Personnel should take all possible
precautions to ensure that mines are not jarred.

— Place sandbags near mines, if possible, to minimize damage to
vehicles and equipment.

— Remove mines from equipment by using a line or other remote
means. Ensure that the entire team is far enough from the mine to
avoid casualties if it explodes.

— Place explosive charges to minimize vehicle damage when
detonating mines on the ground.

Clearance team personnel—

— Clear sufficient mines to allow for mission accomplishment if the
position cannot be evacuated.

— Clear and mark communication lanes between positions.
Continuethe mission.

Mine Awareness F-15

C3, FM 20-32

Survival Rules

Many of our allies have extensive experience in mine operations. Among them
is Canada. They have produced several manuals and videotapes on mine
awareness and have developed the following survival rules. They are very
practical and can be applied to our soldiers as well.

/ fyou did not drop it, do not pick it up.

All terrain and structures are potentially mined or booby-trapped.

Beware of areas associated with basic human needs. They could be
mined or booby-trapped.

Immediately report all confirmed or suspected mines.

Leave mine disposal to theEOD personnel and combat engineers.

Avoid touching or removing foreign objects, no matter how attractive
They could be mined or booby-trapped.

Avoid verges because they could be mined. Stay on the traveled road.

Mark and avoid UXOs if possible Consider them unstable

Develop and rehearse effective evacuation drills.

A convoy provides better protection against mine and UXO threat than a
single vehicle. In convoy movement, some rules of thumb should be followed:

• The lead vehicle should be one of the heaviest (2V2-ton, 5-ton) vehicles
in the unit and be hardened against a minethreat.

• A high-mobility multipurpose, wheeled vehicle (HMMWV) or a
HEMMT should not lead a convoy unless absolutely necessary. These
vehicles are extremely vulnerable to mine and UXO threat and are
difficult to harden without commercial products.

Casualty Treatment and Evacuation

Casualty treatment and evacuation should be a part of every mission order.
Incorporate the following elements into the unit SOP, and ensurethat soldiers
understand them. Emphasize that rushing to help a mine victim can lead to
the rescuer becoming a casualty.

Reassure the casualty.

Do not panic and create another casualty.

Call higher headquarters at the earliest opportunity, and request a
specialist engineer and medical help as soon as possible.

Extract yourself and mark the path as you go.

Reenter along the marked path.

Clear a path to the casualty.

Administer first aid.

Recover the casualty.

F-16 Mine Awareness

C3, FM 20-32

LEADER

• Mark the area after it is clear, record it on the map, and report to
higher headquarters.

Medical personnel and combat lifesavers should anticipate and train for the
following injuries:

Blast injuries with fragments embedded.

Burns.

Fractures.

Traumatic amputations.

Blunt trauma.

Psychological anxiety reaction.

Leader skills in effective planning, risk management, and mine-data tracking/
dissemination can greatly enhance force protection and reduce casualties in a
mined environment. Unit leaders must train themselves and their
subordinates on mine-awareness tasks.

Risk Management

Risk management reduces the frequency of mine and UXO strikes and
diminishes the physical effects when they do occur. It is used to identify
hazards, define risks, identify methods for control, and identify
responsibilities for implementation. The risk-management process enables
commanders and staffs to define acceptable risk levels and implement
controls until risks are commensurate with the mission. Risk management is
a simple, five-step process:

Identify hazards.

Assess the risk of each hazard.

Make risk decisions and develop controls.

Implement controls.

Supervise.

Identify Hazards

This is often the most difficult part of risk management. A mine hazard is the
condition that results from the interactions of a mine, a catalyst (such as
activation from a soldier or vehicle), and a common spatial relationship. These
hazards are defined in terms of mine types (AT, AP, fuses, metal content,
AHD), how a soldier might encounter mines (dismounted or mounted and the
type of vehicle), and the locations where encounters would be most likely.
M ines are seldom employed in isolation, so complete hazard definition
includes the complex obstacle and the covering fires.

Mine Awareness F-17

C3, FM 20-32

Assess the Risk of Each Hazard

This requires determining the probability of a mine strike and the effects of
the strike. An effective risk assessment is critical for evaluating the combat
effectiveness of a unit in a mined environment. Risk-assessment criteria is
developed by using Table F-l. A sample risk assessment is shown in Table F-2,
page F -19.

Table F-1 . Risk-assessment criteria

Hazard Probability

Frequent

(A)

Probable
(B)

Occasional

(C)

Remote
(D)

Improbable

(E)

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Single Item

Likely to

occur

frequently

Will occur
several times
during life of
item

Likely to
occur
sometime
during life of
item

Unlikely, but
possible to
occur during
life of item

So unlikely,
can assume
occurrence
will not take
place

Fleet/Inventory

Occurs
continuously

Will occur
frequently

Will occur
several times

Unlikely but
reasonably
expected to
occur

Unlikely to
occur, but
possible

CATASTROPHIC
(death or system
loss)

I

High

High

High

High

Medium

CRITICAL
(severe injury or
occupational
illness or major
damage)

II

High

High

High

Medium

Low

MARGINAL
(minor injury or
occupational
illness or minor
damage)

III

High

Medium

Medium

Low

Low

NEGLIGIBLE
(less than minor
injury, illness, or
damage)

IV

Medium

Low

Low

Low

Low

Make Risk Decisions and Develop Controls

This step requires decision makers to identify actions that can reduce the
probability and/or severity to acceptable levels. This may be accomplished by
taking actions to reduce the probability of a mine strike or by providing more
protection to the soldier or materiel to reduce severity of a mine strike. Often,
it is a combination of the two.

I mplement Controls

Leaders must apply the identified controls to reduce the probability and
severity of a mine strike.

F-1 8 Mine Awareness

C3, FM 20-32

Table F-2. Sample risk assessment

DIRECTIONS: Circle the appropriate number in each section and total them. Appropriate directions
are at the end of the assessment block.

TRAINING (Circle One)

1 . Experience working in mined areas

2. No experience working in mined areas, but trained

3. No experience or training working in or around mined areas
TYPE OF AREA (Circle One)

1 . Area known by friendly forces to be clear of mines

2. Old confrontation line or suspected mined area

3. Area known to be mined
LIGHT AND WEATHER (Circle One)

1 . Daylight with clear weather

2. Daylight with poor weather

3. Darkness
MISSION (Circle One)

1 . One that your soldiers have done before

2. One that your subordinate leaders have done before

3. An unfamiliar type of mission
ON OR OFF ROAD (Circle One)

1 . Approved division/corps route

2. Paved road

3. Un paved road

4. Cross-country
SLEEP (Circle One)

1 . 6 hours of sleep in last 24

2. 4 hours of sleep in last 24

3. 2 hours of sleep in last 24

4. Awake for more than 24 hours.

TYPE OF VEHICLES IN CONVOY (Circle One)

1 . Armored

2. Mixed, armored vehicles leading

3. Wheeled

4. On foot

AVAILABILITY OF MINE INFORMATION (Circle One)

1. Updated mined-area graphics in each vehicle

2. Updated mined-area graphics in the lead vehicle or a reliable, knowledgeable guide is available

3. No upgraded mined-area graphics are available
GROUND COVER (Circle One)

1 . Dry, hard ground with short grass

2. Dry, hard ground with long grass or vegetation

3. Wet, muddy ground or snow less than 10 centimeters deep

4. Snow more than 10 centimeters deep
ROAD USE (Circle One)

1 . Heavy tracked vehicles or trucks recently used the road

2. Light wheeled vehicles recently used the road

3. No traffic observed on the road; some tire marks

4. No traffic observed on the road; no tire marks

10-16 Continue the mission. Keep following training and common-sense rules that apply to working

around mines.

17-24 Continue the mission. Remember to stress safety and mine awareness when you brief soldiers.

Ensure that leaders maintain positive control of personnel.

25-35 Consider postponing the mission until better conditions are attained. If you must continue the

mission, constantly stress mine awareness and safety. Ask higher headquarters for engineer support to

accomplish the mission. Conduct mine-awareness training.

Mine Awareness F-19

C3, FM 20-32

Supervise

This step ensures that controls are implemented and that a measure of
quality control exists to ensure a quantified level of clearance.

The key to using risk management successfully is to employ it at each
echelon— from the commander, through the tactical planner, to the soldiers
executing the mission. Each level identifies hazards, eliminates or reduces
hazards as feasible, and communicates the residual hazards to the next lower
echelon. As such, each echelon works as a filter to control unacceptable risks.

• Training provides soldiers with an understanding of equipment
limitations and plays a critical role in the risk-management process.
Capabilities and limitations of Army systems are taken into
consideration during the development of doctrine and TTP.

• Risk management at the tactical planning level requires a thorough
knowledge and awareness of the hazards and potential controls that
can be employed. The planning process requires a methodical and
disciplined technique to identify the hazards and develop appropriate
controls for operating in a mined environment. The controls for
countermine operations, discussed in Chapters 9 and 11 and in FM
3-34.2, provide a framework for risk-managing hazards associated
with mines.

• The execution level is the culminating point of risk management. It is
where soldiers and leaders employ the systems provided to accomplish
the mission. The amount of residual hazards remaining after the
filtering process from echelons above may well determine success. The
individual soldier is the last element to control any residual hazards.

Optimizing the components of risk management at the tactical planning level
is more challenging as emerging technologically dependent systems bring
more variables into the mission. While tactical intelligence is the key element
in identifying mine-related hazards, technical knowledge is the key element in
assessing the risks associated with mine hazards. This knowledge assimilates
the tactical intelligence with the capabilities of the unit's equipment, the
performance of threat mines, and the protection provided to our soldiers by
their vehicles or personal protective equipment. The staff engineer, using his
engineer C 2 system to risk-manage each COA, provides the maneuver
commander and his staff with information on risks and potential controls
early on in the planning process. Each subsequent commander must perform
the same analysis and incorporate the mine threat intorisk management.

Recording and Mine-Data Tracking

Obtaining and disseminating information are the keys to battlefield
management. Units encountering minefields or explosive devices should
follow a five-step process— stop, secure, mark, report, and avoid. Units must
provide adequate information to their higher headquarters to ensure that
follow-on elements are well informed. Information must include known or
suspected minefield locations, types of mines (if known), the marking method,
the time encountered, and any additional information that may be of use to
the clearing unit.

F-20 Mine Awareness

C3, FM 20-32

Division and maneuver brigade engineer planning cells must establish a
central control cell for mine-clearance information. The central control cell—

• Maintains a current situation map and overlay that depicts friendly
and enemy mines and obstacles.

• Maintains and updates information on minefield tracking and route
status.

• Receives and maintains minefield recording forms within the unit's
AO (includes host-nation minefield data if available).

• Maintains a database of mine information.

• Processes, analyzes, updates, and disseminates the information to
subordinate commanders and staff.

Mine-Incident Report

TRAINING

A mine incident includes any unplanned activity involving a mine, UXO, or
booby trap. It also includes near misses that could have resulted in potential
damage or injury. The mine-incident report is a technical report that follows a
serious-incident report. The report should be submitted as soon as possible
(the local SOP will indicate time requirements). A sample mine-incident
report is shown in Figure 11-12, page 11-26.

Modern combat is complex, lethal, and demanding. Soldiers must be capable
of performing their missions in any type of battlefield environment. Current
doctrine and TTP provide soldiers with guidelines to accomplish their tasks
and quality equipment provides the means. The common thread that connects
doctrine, tactics, and equipment is quality training. To fight and win, units
must train their soldiers to execute all wartime missions successfully. They
must use every training opportunity to improve soldier, leader, and unit task
performance. Without quality training, no amount of world-class equipment
can make the soldier effective or make him survive in a wartime environment.
Even the best doctrine in the world is worthless unless soldiers receive
effective training. This is especially true with mine-awareness training.

Soldiers must be trained to think mine awareness as well as perform mine-
related actions. Decisions, actions, and reactions must become automatic to
every soldier. This requires that all soldiers receive mine-awareness training
early in their careers. It must begin at early entry training with basic
individual tasks and continue through advanced unit training with collective
tasks. Soldiers who survive mine threats can survive mine warfare, but it
requires continual training.

Individual Training

Basic Mine-Awareness Training

This is the most important phase for preparing soldiers to survive in a mine
environment. Individual soldiers must be trained to a level that meets the
environment they will face on the modern battlefield. Basic mine-awareness
tasks (mine detection, survival rules, minefield indicators, and procedures for
self-extraction from a minefield) must begin early in the soldier's career.

Mine Awareness F-21

C3, FM 20-32

With an estimated 80 to 100 million mines deployed worldwide, countermine
considerations must become second nature to mission planners. From CSS
operations in the rear area to close combat operations in the main battle area,
there is no pi ace on the battlefield that is safe from mines. This is especially
true with the threat of SCATM I NEs that are deployed from aircraft and
indirect-fire sources. The need for initial countermine training will get more
critical as the modern battlefield becomes more lethal.

Annual Mine-Awareness Training

Units exercising military skills at the National Training Center, J oint Reserve
Training Center, or the Combat Maneuver Training Center can reinforce and
evaluate their awareness training. Soldiers should be fully trained on the
individual and collective tasks that are required to support their unit's mine-
related missions before deploying to the combat training centers. An effective
method to meet this challenge is a well-planned annual training program that
trains soldiers on individual and collective mine-awareness tasks. The plan
should address the requirements for initial collective-task training and
sustainment training.

P redeployment Mine-Awareness Training

With an ever-changing global environment, the probability of projecting US
forces to various geographical locations is very real. It is extremely critical
that units be situationally aware. Each flash point in the world contains its
own type of threat. Many of these threats can be neutralized or reduced
through quality predeployment training. Quality predeployment mine-
awareness training enhances the ability of the unit to perform its mission and
increases the confidence of soldiers.

Units must train intensively when alerted for a deployment. Predeployment
training is the time to polish and refine training and to focus on theater-
specific operations. Predeployment training is intended to augment individual
and collective training, not replace it.

In-Theater Mine-Awareness Training

Training does not end with predeployment training. Units must train in the
country where they deploy. They need to plan and conduct routine
sustainment training on individual and collective mine-awareness tasks. This
is an essential ingredient of force- protect ion operations. I n-theater mine-
awareness training reinforces the soldier's existing skills and places mine
survival in theforefront of each soldier's mind.

Leader Training

Officers and NCOs must receive mine-awareness training in basic and career
courses. Commissioned and noncommissioned leaders must be trained on the
use and the employment of the equipment that they will use in the field.
Officer basic courses and officer and NCO advanced courses must include
access to modeling/simulation training. Using modeling/simulation enables
the leader to practice decision-making, employment, and sustainment
operations in a simulated mine environment. This develops the situational
awareness required for timely, accurate decisions.

F-22 Mine Awareness

C3, FM 20-32

Unit Training

The Army Training and Evaluation Program remains the most effective
measure of individual and collective training effectiveness short of actual
combat. It provides leaders with the opportunity to verify the effectiveness of
virtual and actual training without endangering soldiers with mine effects.
Units must include mine-threat scenarios in their home-station training
exercises. Basic missions include minefield detection, reduction, marking,
proofing, and recording. Commanders are required to assess their unit's state
of proficiency in mine-awareness tasks on a routine basis.

Mine awareness is a critical, perishable skill. It must be trained effectively
and sustained on a continuous basis. If a unit properly trains its soldiers on
mine awareness, it will maintain its force, boost its soldiers' confidence in
their abilities, and accomplish its mission more effectively. Mine awareness is
not a liability; it is an investment in a unit's future.

Mine Awareness F-23

Appendix G

Countermine Data

This appendix provides a compilation of countermine information to assist
commanders in the decision-making process for countermine operations.

BREACHING ASSETS VERSUS THREAT OBSTACLES

Tables G-l and G-2, pages G-2 through G-8, provide general guidance on the
effect of breaching assets versus threat obstacles.

FOREIGN MINE DATA

Tables G-3 through G-7, pages G-9 through G-12, provide foreign mine
characteristics.

FOREIGN MINEFIELD EMPLACEMENT DATA

Table G-8, page G-13, provides foreign minefield emplacement data.
I nformation is presented in the probability of occurrence based on historical
data.

FOREIGN MINE DELIVERY SYSTEMS

Table G-9, pages G-14 and G-15, contains characteristics of foreign mine
delivery systems.

NOTE: Blank areas in the above tables indicate that the information
is not applicable or that it was unavailable when this manual was
published.

Countermine Data G-1

FM 20-32

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in immediately marking the breached lane.

Live mines remain in both berms and may
roll back into the cleared lane. Over time,
these may vibrate free and roll back into the
breached lane.

Normally used to detect the leading edge of
a conventionally laid tactical minefield and
to proof lanes/routes cleared by other
means.

Use caution when crossing on an AVLB.

May become stuck or ineffective in muddy
conditions.

The MCR is vulnerable to coupled mines.

The MCR is designed to withstand up to
two detonations per side.

The MCR clears a 160 inch-wide lane but
leaves a 72 inch-wide area uncleared in the
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M113 also has 72 inches between tracks
and must use extreme caution when
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Provides a 0.6- x 45-m footpath from a
25-m standoff

Can be deployed by two men in 2 minutes

Consists of two manpack units weighing
approximately 55 lbs each

Provides a 0.6- x 1 5-m footpath

Can be deployed by a squad in 5 minutes

Consists of ten 1 .5-m-long sections
weighing 13 lbs each

Is ineffective against AT mines

Has a range of 80 to 100 m when
launched

Can be thrown 15 to 20 m when hand
thrown

Must consider the lethal range/radius (up
to 90 m in some cases) of fragmenting AP
mines that may be encountered, and
select a covered position or move back an
adequate distance before pulling the
grapnel

Helps increase confidence by grappling an
area several times

Is hampered by thick vegetation/overhead
obstructions which may reduce the range/
effectiveness of the WLGH

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footpath

Clears a
footpath

Is somewhat
effective at
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wire-fused
mines
integrated
with wire
obstacles

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may snag
the wires
between the
observer and
his mines

Influence-
Fused AP
Mine

03

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Is ineffective;
however, it
may snag
the wires
between the
control unit
and its mines

Trip-Wire/Break-
Wire-Fused AP
Mine

Effectively cuts 99
percent of trip
wires in its path

Effectively cuts 99
percent of trip
wires in its path

Effectively clears
99 percent of trip
wires/break wires
in a single pass

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Effectively clears
95 percent,
including blast-
resistant types

Effectively clears
85 percent of
simple pressure-
fused mines; is
less effective
against blast-
hardened mines

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Is used as a last resort

Is a relatively slow method for clearing
visually detected ordnance

Ensures protection of weapons operator

Works better with larger caliber weapons
(up to 25 mm), incendiary ammo works
best

May be the only option open to artillery,
MP, and transportation units for dealing
with SCATMINEs in the absence of
engineers and reduction assets

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Ensure that
observer is
neutralized
before
approaching

Ensure that
observer is
neutralized
before
approaching

Is effective
against
surface-laid
munitions

Influence-
Fused AP
Mine

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Trip-Wire/Break-
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Mine

Is ineffective; the
soldier must rely
on clearance by
other means and
visual detection

Do not cut a slack
wire until both
ends have been
checked if break-
wire-fused mines
may be present;
do not cut taught
trip wires until both
ends have been
checked for
tension-release
FDs

Is effective against

surface-laid

munitions

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Is effective at
locating all buried
mines; however,
extreme caution
should be used
when probing for
small mines (less
than 3-inch dia)
and sensitive
mines (more than
1 lbs actuating
force)

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Do not use if the presence of AT mines is
suspected, because AT mines can destroy
the MiniFlail.

Can clear at a rate of about 1 ,500 square
meters per hour

Is less effective against low-metal mines
and in areas contaminated with metal
fragments (artillery, mortar, small arms) or
areas that have heavily mineralized soils

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Is armored
against
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threats

Is vulnerable
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blast mines

Ensure that
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neutralized
before
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Influence-
Fused AP
Mine

03

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Cannot detect
monofilament
fishing line used
for trip wires; it is
undetectable by
theAN/PSS-12.
Visual detection
and other
neutralization
means should be
used first in any
area suspected of
having trip wires.

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Is effective against
simple pressure-
fused AP mines

Is less effective
against blast-
hardened AP
mines

Is very effective at
finding metallic
mines

Is less effective
against low-metal
mines

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Ensure that
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neutralized
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Can reduce

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severity

Ensure that
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Can reduce
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Can reduce
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mines

Trip-Wire/Break

Wire-Fused AP

Mine

Place at least a
1-lb charge within
6 inches of the
mine after the
mine at the end of
a trip wire has
been located

Can use elevated
charges if
necessary against
the claymore and
stake-type mines

Can reduce
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against
fragmenting mines

Can reduce
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Place at least a 1 -
pound charge
within 6 inches of
simple pressure-
fused mines

Ensure that the
charge is placed
within an inch of
blast-hardened
mines

May be effective
against very small
(up to 1 oz of
explosive) mines

Is ineffective
against mines with
more than 1-oz
explosive weight

Will protect
personnel near
the individual who
detonates a
pressure-fused AP
mine

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G-12 Countermine Data

FM 20-32

Table G-8. Foreign emplaced

minefields

Russia

Iraq

North Korea

Bosnia

Manually

Antitrack AT

1

1

1

1

Antihull AT

2

3

3

2

Side-attack AT

3

4

3

4

Blast AP

1

1

1

1

Directional AP

1

4

1

Bounding AP

1

1

2

1

Stake AP

1

4

1

1

Mechanically

Antitrack AT

1

1

1

4

Antihull AT

2

3

1

Vehicle Scattered

Antitrack AT

1

Antihull AT

1

Blast AP

Directional AP

Bounding AP

Simple Frag

1

Artillery/MLRS

Antitrack AT

1

4

Antihull AT

1

1

Blast AP

Directional AP

Bounding AP

Stake AP

1

Helicopter/Fixed-Wing Aircraft

Antitrack AT

1

1

Antihull AT

1

Blast AP

1

1

Directional AP

Bounding AP

Stake AP

1

NOTE: Scored from

1 (most common) to 4 (very rare).

Countermine Data G-13

FM 20-32

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Countermine Data G-15

FM 20-32

G-16 Countermine Data

Appendix H

Metric Conversion Chart

This appendix complies with current Army directives which state that the
metric system will be incorporated into all new publications. Table H-l is a
conversion chart.

Table H-1. Metric conversion chart

US Units

Multiplied By

Metric Units

Feet

0.3048

Meters

Inches

2.54

Centimeters

Inches

0.0254

Meters

Inches

25.4001

Millimeters

Miles

1.6093

Kilometers

Pounds

453.59

Grams

Pounds

0.4536

Kilograms

Metric Units

Multiplied By

US Units

Centimeters

0.3937

Inches

Grams

0.03527

Ounces

Kilograms

2.2046

Pounds

Kilometers

0.62137

Miles

Meters

3.2808

Feet

Meters

39.37

Inches

Meters

1.0936

Yards

Millimeters

0.03937

Inches

Metric Conversion Chart H-1

FM 20-32

H-2 Metric Conversion Chart

Glossary

1LT

1SG

2LT

AA

ACE

ACR

AD

ADA

ADAM

ADE

AHD

Al

ALO

ammo

AO

AP

APB

APC

APDS

APF

APL

APOBS

AR

ASP

first lieutenant

first sergeant

second lieutenant

avenue of approach

armored combat earth mover

armored cavalry regiment

armor division

air-defense artillery

area-denial artillery munition

assistant division engineer

antihandling device

area of interest

air liaison officer

ammunition

area of operations

antipersonnel

antipersonnel blast

armored personnel carrier

armor-piercing discarding sabot

antipersonnel fragmentation

antipersonnel land mine

Antipersonnel Obstacle Breaching System

Army regulation

ammunition supply point

Glossary-1

FM 20-32
ASTAMIDS

Airborne Standoff M inefield Detection System

AT

antitank

atk

attack

ATP

ammunition transfer point

attn

attention

AVLB

armored vehicle-launched bridge

AVLM

armored vehicle-launched MICLIC

BAI

battlefield air interdiction

bde

brigade

BICC

battlefield information control center

BLPS

ballistic and laser protective spectacles

bn

battalion

BOS

Battlefield Operating System

BP

battle position

BRDEC

US Army Belvoir Research, Development, and Engineering Center

C

Celsius

C 2

command and control

CA

civil affairs

cal

caliber

CAS

close air support

cdr

commander

CEV

combat engineer vehicle

CG

commanding general

CHS

combat health support

CL

centerline

cm

centimeter(s)

cmd

command

CMMC

corps material-management center

Glossary-2

FM 20-32

CO

COA

COB

comp

CS

CSR

CSS

CTCP

cu

Czech

d

DA

DAO

DCU

det

det

dia

div

DMMC

DOD

DODIC

DST

DTG

DZ

EA

ea

EBA

EDD

company

course of action

civilian on the battlefield

composition

combat support

controlled supply rate

combat service support

combat trains command post

cubic

Czechoslovakia

day

Department of the Army

division ammunition officer

dispenser control unit

detonated

detonating

diameter

division

division material-management center

Department of Defense

Department of Defense identification code

decision support template

date-time group

drop zone

engagement area

each

engineer battlefield assessment

explosive detector dog

Glossary-3

FM 20-32
EFP

explosive-formed penetrating

EID

end item code

EM

enlisted member

engr

engineer

ENS

Explosive Neutralization System

EOD

explosive ordnance disposal

ESMB

explosive standoff minefield breacher

F

Fahrenheit

FCP

forward command post

FCS

fire control system

FD

firing device

FECS

Field-Expedient Countermine System

FIST

fire-support team

FLOT

forward 1 i ne of own troops

FM

field manual

FM

frequency-modulated

FMFM

Fleet Marine Force manual

FPF

final protective fires

frag

fragmentation

FRAGO

fragmentary order

FSB

forward support battalion

FSC

federal stock classification

FSCL

fire-support coordination line

FSCOORD

fire-support coordinator

FSE

fire-support element

ft

foot, feet

ft

fort

FWF

former warring faction

Glossary-4

FM 20-32

g gram(s)

G2 Assistant Chief of Staff, G2 (I intelligence)

G3 Assistant Chief of Staff, G3 (Operations and Plans)

G4 Assistant Chief of Staff, G4 (Logistics)

GDP general defense plan

Ger Germany

GPS global-positioning system

H hour of execution

HE high-explosive

HEI-T high-explosive incendiary tracer

HEMMS hand-emplaced minefield marking set

HEMTT heavy expanded mobility tactical truck

HEXJ AM hand-emplaced, expandable jammer

HMMWV high-mobility, multipurpose, wheeled vehicle

HQ headquarters

hr hour(s)

HTF how to fight

hvy heavy

I BASIC Improved Body Armor System, Individual Countermine

ID infantry division

I DA improved dog-bone assembly

IFV infantry fighting vehicle

ILLUM illumination

IMU inertial measurement unit

in inch(es)

inf infantry

IOE irregular outer edge

IP improved plow

Glossary-5

FM 20-32
IPB

intelligence preparation of the battlefield

IR

infrared

ITV

improved TOW vehicle

IVMMD

interim vehicle-mounted mine detector

JAAT

joint air-attack team

J an

J anuary

Jul

July

K-Kill

catastrophic kill

kg

kilogram(s)

km

kilometer(s)

kph

kilometers per hour

KW

Kiowa Warrior

lb

pound(s)

LBE

load-bearing equipment

LE

low explosive

LED

light-emitting diode

LIN

line item number

LM

landmark

LOC

lines of communication

LOGPAC

logistics package

LRA

local reproduction authorized

LRP

logistics release point

LRSD

long-range surveillance device

LZ

landing zone

m

month

m

meter (s)

M-Kill

mobility kill

M-S

Miznay-Schardin

Glossary-6

C2, FM 20-32

mag

Mar

MBA

MC

MCAP

MCB

MCD

MCO

MCOO

MCR

MCRP

MDI

MDV

Met+VE

METL

METT-TC

MHE

MICLIC

Ml DAP

MILSTD

min

min

MLRS

mm

MOBA

MOD

MOPMS

MOPP

magnetic

March

main battle area

mobility corridor

mine-clearing/armor-protection kit

mine-clearing blade

magnetic coupling device

Marine Corps order

modified combined obstacle overlay

mine-clearing roller

MarineCorps reference publication

modernized demolition initiation

mine-detection vehicle

meteorological data/velocity error

mission-essential task list

mission, enemy, terrain, troops, time available, and civilian considerations

material handling equipment

mine-clearing line charge

minefield-detection algorithm and processor

military standard

minute(s)

minimum

Multiple-Launched Rocket System

millimeter(s)

military operations in built-up areas

mobi I e obstacl e detachment

Modular Pack Mine System

mission-oriented protective posture

Glossary-7

FM 20-32
MOOTW

military operations other than war

MOUT

military operations on urbanized terrain

MP

military police

MRB

motorized rifle battalion

MRC

motorized rifle company

MRR

motorized rifle regiment

MSD

movement support detachment

MSR

main supply route

NA

not applicable

NAI

named area of interest

NATO

North Atlantic Treaty Organization

NAVSEA

Naval Sea Systems Command

NBC

nuclear, biological, chemical

NCO

noncommissioned officer

NCOIC

noncommissioned officer in charge

NE

northeast

NGO

nongovernment organization

NLT

no later than

nm

nautical mile

no

number

NSN

national stock number

OBSTINTEL

obstacl e i ntel 1 i gence

Oct

October

OIC

officer in charge

OP

observation post

OPCON

operational control

OPLAN

operation plan

OPORD

operation order

Glossary-8

C2, FM 20-32

P

pam

PIR

PIRS

PL

PL

PLS

pit

PSG

psi

PSYOP

pt

PVO

QASAS

R&S

RAAM

RAC

RCU

RDX

recon

rep

RF

ROKUS

RP

RSO

RTO

S&A

pace(s)

pamphlet

priority intelligence requirement

passive infrared sensor

platoon leader

phase line

palletized load system

platoon

platoon sergeant

pounds per square inch

psychological operations

point

private volunteer organization

quality assurance ammunition specialist

reconnaissance and surveillance

remote anti armor mine

risk-assessment code

remote-control unit

cyclonite

reconnaissance

representative

radio frequency

Republic of Korea, United States

reference point

range safety officer

radio-telephone operator

safing and arming

Glossary-9

FM 20-32
S&H

safety and handling

S&T

supply and transport

S2

Intelligence Officer (US Army)

S3

Operations and Training Officer (US Army)

S4

Supply Officer (US Army)

SAW

squad automatic weapon

SCATMINE

scatterable mine

SCATMINWARN

scatterable minefield warning

set

scout

SD

self-destruct

SE

southeast

SEAD

suppression of enemy air defense

sec

second (s)

SEE

small emplacement excavator

SFC

sergeant first class

SFC

sergeant first class

SFF

self-forging fragmentation

SIR

serious incident report

SITEMP

situation template

SLAM

selectable lightweight attack munition

SOEO

scheme of engineer operations

SOF

special-operations forces

SOP

standard operating procedure

SOSR

suppress, obscure, secure, and reduce

SPECS

Special Protective Eyewear Cylindrical System

SPOTREP

spot report

SSG

staff sergeant

SSN

social security number

Glossary-10

FM 20-32

STANAG

STP

T/MDV

TACC

TAHQ

TAI

TC

TC

TCP

TCP

TF

tm

TM

TMD

TNT

TO

TO

TOC

TOW

TRADOC

TRP

TTP

UAV

UK

UL

US

USAF

USN

International Standardization Agreement

soldier training publication

towing/mine-detection vehicle

tactical air control center

theater army headquarters

target area of interest

track commander

training circular

traffic-control post

tactical command post

task force

team

technical manual

tactical-munition dispenser

trinitrotoluene

theater of operations

Air Force technical order

tactical operations center

tube-launched, optically tracked, wire-guided missile

United States Army Training and Doctrine Command

target reference point

tactics, techniques, and procedures

unmanned aerial vehicle

United Kingdom

Underwriters Laboratories, Incorporated

United States

United States Air Force

United States Navy

Glossary-11

FM 20-32
UTM

U niversal Transverse Mercator

UXO

unexploded ordnance

vs

versus

W

width

w/

with

WLGH

weapon-launched grapnel hook

WO

warning order

WP

white phosphorus

XO

executive officer

y

year

Yugo

Yugoslavia

Glossary-12

C2

References

SOURCES USED

These are the sources quoted or paraphrased in this publication.

I oint and Multiservice Publications

AR 385-63. Policies and Procedures for Firing Ammunition for Training, Target Practice and
Combat pi CO P3570.1A}. 15 October 1983.

FM 20-11. Military Diving fJAVSEA 0910-LP -708-8000}. 20 J anuary 1999.

FM 90-3. Desert Operations fMFM 7-27}. 24 August 1993.

FM 90-13. River-Crossing Operations fACWP 3-17.1} 26 J anuary 1998.

F M 101-5-1. Operational Terms and Graphics fACRP 5-2A} 30 September 1997.

STAN AG 2036. Land Mine Laying, Marking, Recording and Reporting Procedures. Edition 5.
12 February 1987.

STANAG 2889. Marking of Hazardous Areas and Routes Through Them. Edition 3.
26 March 1984.

STANAG 2990. Principles and Procedures for theEmployment in Land Warfare of Scatterable
Mines With a Limited Laid Life- ATP-50. Edition 1. 15 September 1988.

TM 5-6665-298-10. Operator's Manual AN/ PSS-12 MineDetecting Set {TM 5-6665-298-10}
28 February 1995.

TM 9-1345-203-12&P. Operator's and Organizational Maintenance Manual (Including Repair
Parts and Special Tools L ist) for L and Mines {TO 11A8-3-1} 14 J anuary 1977.

TM 9-2590-509-10. Operator's Manual MineClearingBladefor Ml, IPM1, or M1A1 AbramsTank
(NSN 2590-01-230-8862) {TM 2590-10/1} 12 April 1990.

Army Publications

AR 40-10. Health Hazard Assessment Program in Support of the Army Materiel Acquisition
Decision Process. 1 October 1991.

AR 385-10. The Army Safety Program. 23 May 1988.

AR 385-16. System Safety Engineering and Management. 3 M ay 1990.

DA Pam 350-38. Standards in Weapons Training. 3 J uly 1997.

FM 1-113. Utility and Cargo Helicopter Operations. 12 September 1997.

FM 3-34.2 (formerly FM 90-13-1). Combined-Arms Breaching Operations. 31 August 2000.

F M 5-7-30. Brigade Engineer and Engineer Company Combat Operations (Airborne Air Assault,
Light). 28 December 1994.

FM 5-10. Combat Engineer Platoon. 3 October 1995.

References-1

C2, FM 20-32

F M 5-34. Engineer Field Data. 30 August 1999.

F M 5-71-2. Armored Task-Force Engineer Combat Operations. 28 J une 1996.

F M 5-71-3. Brigade Engineer Combat Operations (Armored). 3 October 1995.

FM 5-100. Engineer Operations. 27 February 1996.

F M 5-170. Engineer Reconnaissance. 5 M ay 1998.

FM 5-250. Explosives and Demolitions. 30 J uly 1998.

FM 90-5 (HTF).y ungle Operations (How to Fight). 16 August 1982.

FM 90-7. Combined Arms Obstacle Integration. 29 September 1994.

FM 90-10 (HTF). Military Operations on Urbanized Terrain (MOUT) (How to Fight).
15 August 1979.

FM 90-10-1. An Infantryman's Guide to Combat in Built-up Areas. 12 May 1993.

F M 101-5. Staff Organization and Operations. 31 M ay 1997.

MILSTD 882C (Revision). System Safety Program Requirements. 19J anuary 1993.

STP 5-12B 1-SM. Soldier's Manual: MOS 12B, Combat Engineer, Skill Level 1. 14 February 2001.

TC 25-8. Training Ranges. 25 February 1992.

TC 31-34. Demining Operations. 24 September 1997.

TM 1-1520-237-10. Operator's Manual forUH-60A Helicopters, UH-60L Helicopters, andEH-60A
Helicopters. 31 October 1996.

TM 9-1095-208-10-1. Operator's Manual for Dispenser, Mine M139 (NSN 1095-01-235-3139)
(EIC: 3V8) with Mounting Kits for 5-Ton Vehicle (1095-01-252-2818) (EIC: 3V9) and M548A1
Vehicle (1095-01-331-6755) (Ground Volcano). 10 J uly 1992.

TM 9-1300-206. Ammunition and Explosives Standards. 30 August 1973.

TM 9-1345-203-12. Operator's and Unit Maintenance Manual for Land Mines. 30 October 1995.

TM 9-1345-209-10. Operator's Manual for Modular Pack Mine System (MOPMS) Consisting of
Dispenser and Mine Ground: M131 (NSN 1345-01-160-8909) Control, Remote Land Mine
System: M71 (1290-01-161-3662) and Dispenser and Mine Ground Training: M136 (6920-01-
162-9380). 31 March 1992.

TM 9-1375-213-12. Operator's and Unit Mai ntenanceManual (I ncluding Repair Parts and Special
Tools List): Demolition Materials. 30 March 1973.

TM 9-1375-215-14&P. Operator's, Unit, Direct Support and General Support Mai ntenanceManual
(I ncluding Repair Parts and Special ToolsList) for Demolition Kit, MineClearing LineCharge
(MICLIC). 31 J anuary 1992.

TM 43-0001-36. Army Ammunition Data Sheets for Land Mines (FSC 1345). 1 September 1994.

References-2

C2, FM 20-32

DOCUMENTS NEEDED

These documents must be avail able to the intended users of this publication.

DA Form 1355. Minefield Record. March 1987.

DA Form 1355-1-R. Hasty Protective Row Minefield Record (LRA). September 2001.

DA Form 2028. Recommended Changes to Publications and Blank Forms. February 1974.

READINGS RECOMMENDED

These readings contain relevant supplemental information.

FM 5-490. Engineer Diving Operations. 31 March 1992.

F M 6-20-40. Tactics, Techniques, and Procedures for FireSupport for Brigade Operations (Heavy).
5 January 1990.

F M 6-20-50. Tactics, Techniques, and Procedures for FireSupport for Brigade Operations (L ight).
5 January 1990.

TM 5-2590-214-10. Operator's Manual for Roller Kit, Mine(NSN 2590-01-134-3724) (EIC:AKZ)
and Mounting Kit, MineClearing Roller (2590-01-235-5458) (EIC:AKZ). 30 March 1993.

TM 9-1095-209-10. Operator's Manual for Mine Dispenser: M138 (Flipper). 29 March 1990.

References-3

FM 20-32

References-4

C3

Index

Airborne Standoff Minefield Detection System,

10-3
air-mission brief, D-13
anchor point, 2-12
anti handling devices, 2-9, 6-31, 6-37

M142 multipurpose FD, 1-7

M5 pressure-release FD, 1-7
antipersonnel mines, 1-5

characteristics, 5-3

installation, A-3, A-7

M 14, 5-3, A-2

M 16, A-6

removal, A-5, A-10

sensing, types of, 1-5

warheads, types of, 1-6
Antipersonnel Obstacle Breaching System

(APOBS), 10-12
antitamper feature, 4-6
antitank mines, 1-4

characteristics, 5-2

M15, A-ll, E-7

M19,A-21, E-7

M21, A-24, E-7
AP SCATMINEs, 3-1

characteristics, 3-2
APOBS. SeeAnti personnel Obstacle Breaching

System,
area clearance, 9-1, 9-7, 11-15
area-denial artillery munitions, 3-11
area-disruption obstacle, 4-10
arming point, D-16
arming time, 3-6, 4-1
armored vehicle-launched MICLIC (AVLM),

10-7
artillery-shell AT device, 13-30
assault force, 11-7
AT SCATMINEs, 3-3

characteristics, 3-4
AVLM. Seearmored vehicle-launched MICLIC.

B

bangalore torpedo, 10-13

barbwireAP device, 13-32

Battlefield Operating System, 2-34

bearing board, 5-6

bearing plate, 5-6

beginning-of-strip marker, 7-2

blasting machine, 3-27

block minefields, 2-13, 6-31, D-6

MOPMS, 3-29

row, 6-31

Volcano, 3-24
booby traps, 13-1

actuation methods, 13-5
booster charge, 1-1
breach force, 11-8, 11-18
breaching, 9-1, 9-2
break wires. See trip wires,
breaking a trip wire, 1-2
bypasses, 10-27
bypassing, 9-2

camouflage, 5-6

catastrophic kill (K-Kill), 1-4

centurion, 4-7

chemical land mines, C-6

claymore device, improvised, 13-31

clearing, 9-6

buildings, 13-19

equipment, 10-7

methods, 13-22

obstacles, 13-21

open areas, 13-18

secure areas, 13-17, 13-21

sequence, 13-15
clusters, 7-4
combat clearance, 13-16
combat engineer vehicle with full-width mine

rake, 10-21
command-detonation, 4-4
control measures

site layout, 6-16, 6-17
control of parties, 13-9
control point, 13-9

lndex-1

C3, FM 20-32

conventional mines, 5-1
countermine data, G-l
countermine operations, C-6

DA Form 1355, 8-3, 12-3
DA Form 1355-1-R, 8-3, 8-17
DCU. See dispenser control unit,
decision and execution, 2-29

obstacle-execution matrix, 2-29

scheme-of -obstacle overlay, 2-29
demining, 9-2, 9-7
density, 3-8
detection, 10-1, 13-15

Airborne Standoff Minefield Detection
System (ASTAM I DS), 10-3

AN/PSS-12 mine detector, 10-3

electronic, 10-3

mine rollers, 10-6

physical (probing), 10-2

visual, 10-1
detonator, 1-1
digging team, 6-16
dispenser control unit (DCU), 3-21
dispensing marker, 3-19
disrupt minefields, 2-10, D-7

MOPMS, 3-29

row, 6-28

Volcano, 3-24
dud pit, D-16

emplacement

ADAM/RAAM,3-13

Gator, 3-16

hasty protective row minefield, 6-34

Hornet, 4-14

MOPMS, 3-28

Volcano, 3-23

water, 12-2
emplacement authority, 3-9
employment

ADAM/RAAM,3-12

Gator, 3-15

MOPMS, 3-28

Volcano, 3-23
employment authority, 6-34
end-of-strip marker, 7-4
engineer divers, 12-1, 12-3
ENS. See Explosive Neutralization System.
ESMB. See explosive standoff minefield

breacher.
expedient devices, 13-29
Explosive Neutralization System (ENS), 10-11
explosive standoff minefield breacher (ESMB),

10-11
extraction

dismounted, F-14

mounted, F-13

FECS. See Field-Expedient Countermine

System,
fencing, 3-33, D-20, D-21
Field-Expedient Countermine System (FECS),

10-22
fire-support coordination line, 3-15
fire-support plan, 2-34
firing mechanism, 1-1, 1-2
fix minefields, 2-11, D-7

MOPMS, 3-30

row, 6-28

Volcano, 3-24
force organization, 9-4
fragment hazard zone, 3-31, 3-32
fuse types, 1-2

gaps, 7-8

Gator, 3-14

gauntlet obstacle, 4-12

grapeshot AP device, 13-32

grapnel hook, 10-22, 10-23

hand-thrown, 10-24

weapon-launched, 10-24
Grizzly, 10-20

H

hand neutralization, 11-21
hand-emplaced explosives, 10-22
hand-emplaced mine marking system

(HEM MS), 10-36
hand-emplaced mines, 5-1
haul capacity, Class I VA/, 2-45
HEM MS. See hand-emplaced mine marking

system.
Hornet, 4-6

lndex-2

C3, FM 20-32

I

BASIC. See Improved Body Armor System,

Individual Countermine,
gniter, 1-1
mproved Body Armor System, Individual

Countermine (I BASIC), 10-19
mproved dog-bone assembly, 10-15, 10-17
mprovised mining, 11-19
ndividual training, F-21
nterdiction weapons, 4-14
nterim vehicle-mounted mine detector

(IVMMD), 10-5
ntermediate markers, 8-10
OE. See irregular outer edge,
irregular outer edge (I OE ), 2-9, 6-2, 6-20, 7-3, 7-

6

baseline, 7-4

short rows, 6-20

short strips, 7-6
IVMMD. See interim vehicle-mounted mine

detector.

landmarks, 6-3, 7-9, 8-9
lane marking, 10-27

NATO standard, 10-36
lane widths, 9-4, 9-6
lane-closure team, 7-15
lanes, 7-7, 9-6

closing, 7-15

reducing, 9-4
laying a minefield, 6-20
laying a row minefield, 6-18, 6-23

drill, 6-18, 6-20
laying party, 6-15, 7-11
layout

siting, 6-16
lethality, 3-5, 3-7
lethality and density, 3-7
life cycle, 3-6

linear obstacle effort, 2-10, 2-39
live-mine firing demonstrations, E-5
live-mine training, E-3
logistical calculations, 6-3, 7-9

M

M 1 and M 2 activators, A-33
M 139 dispenser, D-2
M14AT mine, 5-3
M 142 firing device, A-32

M15AT mine, 5-1

M16AP mine, 5-3, 5-4, E-5

M18A1AP munition, E-6

M 18A1 Claymore munition, 4-2

M19AT mine, 5-1, 5-2

M21AT mine, 5-1, 5-2

M5 firing device, A-30

M58A4 mine-clearing line charge, 10-7

M60 Panther, 10-18

M 603 fuse, 5-2

M606 integral fuse, 5-2

M 624 fuse, 5-2

M71 remote-control unit, 3-26

M 87 mine canister, D-l

M87A1 mine canister, D-l

M 93 Hornet, 4-6, B-l

magnetic-influenced mine, 4-3

manual breaching, 10-22

manual obstacle reduction, 10-22

markers, D-13

entrance, 10-25

entrance funnel, 10-26

exit, 10-26

far recognition, 10-26

final-approach, 10-26

handrail, 10-25
marking, 3-29, 3-30, 9-7, 10-24, 13-9, 13-18
marking devices, 10-34
marking of minefields and obstacle groups, 2-

52
marking party, 6-15, 7-11
marking procedures, 6-25
MICLIC. See mine-clearing line charge,
mine

clusters, 6-2, 7-1

components, 1-2

emplacement, 7-13

incident, 11-26

removal, 6-36, 11-21

rows, 6-1, 6-16, 6-34

spacing, 6-17

strips, 7-1

visual indicators, F-l
mine detector, AN/PSS-12, 10-3, F-3
mine dump, 2-43, 6-15
mine roller, 10-6
mine training, E-l
mine-awareness training, F-21
mine-clearing blade, 10-14
mine-clearing line charge (MICLIC), 10-7

lndex-3

C3, FM 20-32

mine-clearing roller, 10-14, 10-16
mine-clearing/armor-protection kit, 10-22
mine-dump party, 6-15, 7-11
minefield

density, 3-14
design, 2-5
gaps, 7-8
handover, 7-19

inspection and maintenance, 2-55
lanes, 6-3, 7-7
marking, 2-49
recording, 6-15
reduction, 10-7
reporting, 6-15
siting, 2-38, 6-15
turnover, 2-52
minefield marking set, 10-36
minefield packages, 2-40, 2-42, 2-43
minefield report and record, 2-53
minefield turnover report, 2-53
minefield variables, 2-7
minefields
block, 6-31

disrupt and fix row, 6-28
hasty protective row, 6-33
nuisance, 7-17
standard pattern, 7-1
turn, 6-29
minefields, types of, 2-1
mine-incident report, F-21
mines

antipersonnel
M 14, 12-10
M 16, 5-3, 5-4, 12-10
M18A1 (claymore), 12-10
M 605 fuse, 5-4
prong-activated, 5-5
trip-wire-activated, 5-5
antitank

M15, 5-1, 12-1
M 603 fuse, 5-2
M 624 fuse, 5-2
M 19, 5-1, 5-2, 12-1

M606 integral fuse, 5-2
M21, 5-1, 5-2, 12-1
sympathetic detonation, 5-8
conventional, 5-1
hand-emplaced, 5-1
mines tally sheet, 7-14
mine-strip packages, 2-43, 2-47
MiniFlail, 10-19

mission analysis, 2-19

mobile obstacle detachment, C-l

mobility kill (M -Kill), 1-4

Modular Pack MineSystem (MOPMS), 3-26,

12-15

employment, 3-28
MOPMS. SeeModular Pack MineSystem.
mousetrap. SeeM5 firing device.

N

NATO markers, 10-36
NATO standard marking, 10-36
neutralization, 9-1
nuisance minefields, 7-17

obscuration, 9-4
obstacle control, 2-14
obstacle control measures, 2-14

belts, 2-16

groups, 2-17

restrictions, 2-18

zones, 2-15
obstacle effects, 2-5
obstacle emplacement authority, 2-14
obstacle intelligence, 9-2
obstacle material

Class IV, 2-39

Class V, 2-39
obstacle numbering system, 8-8
obstacle planning, 2-19
obstacle siting, 2-37
obstacle-turnover work sheet, 2-54
outriggers, 12-2
overlay symbols, 8-25

Panther, 10-18

phony minefields, 12-15

planning considerations, 11-17

planning factors, 2-20

planning process (air Volcano), D-ll

platoon-size sweep team, 11-8

platter charge, 13-30

plowing, 10-16

pressure plates, 5-4

probability of encounter, 2-8

probability of kill, 2-9

probes, 10-22

probing, 10-2, F-2

lndex-4

C3, FM 20-32

progress report, 11-23
prongs, 5-4

proofing, 9-2, 9-7, 10-24
protective obstacles, 2-5

RAAM. See remote anti armor mine.

radio-frequency jamming devices, 4-6

ranges of common weapons, 2-23

reconnaissance, 9-2

recording and mine-data tracking, F-20

recording party, 7-11

reduction, 9-1, 9-4, 10-1

regular strips, 7-5

reinforce a conventional minefield, 4-8

remote anti armor mine (RAAM ), 3-11, 3-12

remote control unit, 3-26

reporting and recording, 13-10

reporting procedures, 6-25

reports

change, 8-3

completion, 8-2

initiation, 8-1

intention, 8-1

spot, 10-7

strip feeder, 6-15, 6-22

transfer, 8-2
resource factors, 2-10, 2-39
responsibilities (air Volcano), D-8
risk assessment, E-8, F-18
risk management, F-17
river mining, 12-1
route clearance, 9-1, 11-1
route clearance, methods of, 11-11
row mining, 6-1

safe standoff distance, 4-9

Hornet, 4-10

MOP MS, 4-9

Volcano, 4-10
safe-separation countdown, 3-6
safety considerations, E-3
safety procedures, 13-14
safety tapes, 7-17
safety zone, 3-26, 3-30, 3-32
sample risk assessment, F-18
scatterable minefield reinforcement, 4-10
scatterable minefield report and record, 8-23,

D-22

scatterable mi nefi eld warning, 3-10, 8-23, 8-24,

D-22
scatterable mines, 3-1

ADAM, 12-13

capabilities, 3-5

Gator, 12-15

RAAM, 12-13

Volcano
air, 12-15
ground, 12-15
scatterable mines, extraction from, F-14
selectable lightweight attack munition

(SLAM), 4-3, B-l

M2, 4-3

M4, 4-3
self-destruct times

SLAM, 4-4

Volcano, 3-21

windows, 3-7
self-forging fragmentation, 3-5
self-neutralization (SLAM), 4-4
sensing, types of, 1-5
setting party, 13-9
side attack (SLAM), 4-4
site layout, 3-24, 6-19, 6-34
siting, 2-37

siting party, 6-16, 7-10
siting-and-recording party, 6-18
situation report, 11-23
skim technique, 10-14
skip zone, 10-11
SLAM. See selectable lightweight attack

munition,
special environments

cold regions, 12-16

desert, 12-17

jungle, 12-17
squad drill, 6-24
STAN AG 2036, 6-1, 6-34, 10-36
STAN AG 2889, 10-36
standard AP minefield, C-4
streambed mining, 12-1
supply operations, 2-39
support force, 11-7, 11-18
suppression, 9-4
sweep operations, 11-13
sweep team

squad-size, 11-10
sympathetic detonation, 5-8, 12-1

lndex-5

C3, FM 20-32

tactical minefields, 2-32

tactical munition dispensers, 3-15

tactical obstacles, 2-5

tactical-obstacle effects, 2-6, 3-7

task organization, 11-16

technical inspections, 2-55, 7-18

Terrabase, D-13

terrain analysis, D-13

theater air-tasking order, 3-15, 3-16

threat

antitrack minefield, C-3

equipment, C-ll

mine operations, C-l

minefield parameters, C-2

mixed minefields, C-5

movement support detachment, C-7
tilt- rod fuses, 5-6
timed-demolition, 4-4
top attack, 4-6
traffic control, 9-6
traffic-control posts, 10-26
trip wires, 1-2, 1-6, 5-4, 6-2, 7-6
tripod, 10-23
turn minefields, 2-12, D-6

MOPMS, 3-29

row, 6-29

Volcano, 3-24
turning points, 7-6
turnover, 2-52

U

uncrating mines, 2-42

urban-area mine employment, 12-6

W

warheads, types of, 1-5
blast AT, 1-5
self-forging fragmentation, 1-5

Volcano, 3-21, 3-23
air, 3-23, D-l
emplacement, 3-23
employment, 3-23
fencing, 3-33
ground, 3-23
M 87, 3-21
M87A1, 3-21
minefields, 3-24
multiple-delivery mine system, 3-21

lndex-6

FM 20-32

By Order of the Secretary of the Army:

DENNISJ . REIMER

General, United States Army

Chief of Staff

Official:

J OEL B. HUDSON
Administrative Assistant to the
S ecretary of the A rmy

DISTRIBUTION:

Active Army, Army National Guard, and US Army Reserve: To be
distributed in accordance with the initial distribution number 111053
requirements for FM 20-32.